The concepts of charging power and charging speed are intrinsically linked, but they aren’t interchangeable and can be confused.
When talking about how quickly an electric vehicle replenishes its battery, two different concepts need to be examined. The first is the maximum charging power, measured in kilowatts (kW), and the second is the charging speed, which measures how many miles of range are added in an hour.
Put simply, you can liken charging power to the rate at which water flows through a hose while charging speed is the rate at which it can fill a barrel. So, when talking about charging power, we’re referring to the rate at which energy is being transferred into an EV’s battery pack. The higher the power, the quicker the vehicle will charge, and the less time you will have to spend waiting for it to finish charging.
Charging power and speed are connected but different
Charging power is how much juice an EV can put into its battery pack while charging speed is how quickly it can add miles of range.
Charging power is a straightforward concept (you get it by multiplying voltage and amperage), and manufacturers list this as one of the headline figures to help sell an EV. Even though most buyers rarely see the maximum advertised charging power because many conditions need to be met for it to be achieved, the fact that their vehicle can charge at, say, 350 kW will help seal the deal and ensure charging station bragging rights.
The fastest way to charge an EV is by using a Level 3 DC (direct current) fast charger, whose power typically ranges between 50 and 350 kW. You can find this type of charger only at a public charging station, and you can’t have one installed in your garage because its power requirement is very high, it needs a strong electrical connection to the grid, and it’s very expensive.
You can install a Level 2 AC (alternating current) charger, though, whose power rating ranges from about 3 kW to 19.2 kW (or 22 kW in Europe). For anything over 11 kW, you will need a special three-phase electrical connection, which isn’t cheap to install, and your local electricity grid may not even be able to support it. But even a 7 kW charger is enough for an overnight top-up.
Charging speed is not as simple to calculate as power because it depends on several factors. The most important factor is charging power, but the size and state of charge of the battery pack being charged are also important. The EV’s battery thermal management system and outside temperature and battery temperature also play a role in how many miles of range can be added in an hour.
Calculating how many miles of range are gained from a certain number of kilowatt hours added also depends on how efficient an EV is. For instance, adding 50 kW in an hour to the battery of a small EV that is light and frugal and charging it almost fully will add significantly more miles than adding 50 kWh to the battery of a big, thirsty pickup truck whose capacity is closer to 200 kWh.
Many smaller EVs with battery packs of 50–60 kWh don’t need the fastest charging power since their batteries can be replenished fairly quickly, even at 50–100 kW. However, if a truck with a big battery like the Chevrolet Silverado EV had that kind of maximum charging power, you would have to wait around for hours to charge it, even when plugged into a station that could deliver the maximum power that it could take.