How long does it take to charge an electric car? Well, there are four main charging speeds for electric cars – slow, fast, rapid and ultra-rapid. These represent the power outputs, and therefore EV charging speeds, available to charge an electric car. Note that power is measured in kilowatts (kW).
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Each charger type has an associated set of connectors that are designed for low or high-power use, and for either AC or DC charging. The following sections offer a detailed description of the main charge point types and the different EV charging connector types that are available.
Ultra-rapid chargers are the fastest way to charge an EV, often found at motorway services or locations close to main routes. Rapid devices supply high power direct or alternating current – DC or AC – to charge an electric car as fast as possible.
Depending on the model, you can charge an electric car to 80% in as little as 10-15 minutes, though an average new EV would take around an hour on a standard 50 kW rapid charge point.
Power from a unit represents the maximum charging speed available, though the car will reduce charging speed as the battery gets closer to full charge. As such, times are quoted for a charge to 80%, after which EV charging speeds tail off significantly. This maximises charging efficiency and helps protect the battery.
All rapid devices have charging cables tethered to the unit, and rapid charging can only be used on vehicles with rapid-charging capability. Given the easily recognisable connector profiles – see images below – the specification for your model is easy to check from the vehicle manual or inspecting the on-board inlet.
Rapid DC chargers provide power at 50 kW (125A), use either the CHAdeMO or CCS charging standards, and are indicated by purple icons on our live desktop map. These are the most common type of rapid EV charge points currently, having been the standard for the best part of a decade.
Both connectors typically charge an EV to 80% in 20 minutes to an hour depending on battery capacity and starting state of charge.
Ultra-rapid DC chargers provide power at 100 kW or more. These are typically either 100 kW, 150 kW, or 350 kW – though other maximum EV charging speeds between these figures are possible. These are the next-generation of rapid charge point, able to keep recharging times down despite battery capacities increasing in newer EVs.
For those EVs capable of accepting 100 kW or more, charging times are kept down to 20-30 minutes for a typical charge, even for models with a large battery capacity. Even if an EV is only able to accept a maximum of 50 kW DC, they can still use ultra-rapid charge points, as the power will be restricted to whatever the vehicle can deal with. As with 50 kW rapid devices, cables are tethered to the unit, and provide charging via either CCS or CHAdeMO connectors.
Tesla’s Supercharger network also provides rapid DC charging to drivers of its cars, but use either a Tesla Type 2 connector or a Tesla CCS connector – depending on model. These can charge at up to 150 kW.
While all Tesla models are designed for use with Supercharger units, many Tesla owners use adaptors which enable them to use general public rapid points, with CCS and CHAdeMO adaptors available. The roll-out of CCS charging on the Model 3 and subsequent upgrading of older models allows drivers to access a greater proportion of the UK’s rapid charging infrastructure.
Model S and Model X drivers are able to use the Tesla Type 2 connector fitted to all Supercharger units. Tesla Model 3 drivers must use the Tesla CCS connector, which is being phased in across all Supercharger units.
Rapid AC chargers provide power at 43 kW (three-phase, 63A) and use the Type 2 charging standard. Rapid AC units are typically able to charge an EV to 80% in 20-40 minutes depending the model’s battery capacity and starting state of charge.
EV models that use CHAdeMO rapid charging include the Nissan Leaf and Mitsubishi Outlander PHEV. CCS compatible models include the BMW i3, Kia e-Niro, and Jaguar I-Pace.
Tesla’s Model 3, Model S, and Model X are exclusively able to use the Supercharger network, while the only model able to make maximum use of Rapid AC charging is the Renault Zoe.
Fast chargers are typically rated at either 7 kW or 22 kW (single- or three-phase 32A). The vast majority of fast chargers provide AC charging, though some networks are installing 25 kW DC chargers with CCS or CHAdeMO connectors.
Charging times vary on unit speed and the vehicle, but a 7 kW charger will recharge a compatible EV with a 40 kWh battery in 4-6 hours, and a 22 kW charger in 1-2 hours. Fast chargers tend to be found at destinations such as car parks, supermarkets, or leisure centres, where you are likely be parked at for an hour or more.
The majority of fast chargers are 7 kW and untethered, though some home and workplace based units have cables attached.
Should a cable be tethered to the device, only models compatible with that connector type will be able to use it; e.g. a Type 1 tethered cable could be used by a first-generation Nissan Leaf, but not a second-generation Leaf, which has a Type 2 inlet. Untethered units are therefore more flexible and can be used by any EV with the correct cable.
Charging rates when using a fast charger will depend on the car’s on-board charger, with not all models able to accept 7 kW or more.
These models can still be plugged in to the charge point, but will only draw the maximum power accepted by the on-board charger. For example, a Nissan Leaf with a 3.3 kW on-board charger will only draw a maximum of 3.3 kW, even if the fast charge point is 7 kW or 22 kW.
Tesla’s ‘destination’ chargers provide 11 kW or 22 kW of power but, like the Supercharger network, are intended only or use by Tesla models. Tesla does provide some standard Type 2 chargers at many of its destination locations, and these are compatible with any plug-in model using the compatible connector.
Almost all EVs and PHEVs are able to charge on a Type 2 units, with the correct cable at least. It is by far the most common public charge point standard around, and most plug-in car owners will have a cable with a Type 2 connector charger-side.
Most slow charging units are rated at up to 3 kW, a rounded figure that captures most slow-charging devices. In reality, slow charging is carried out between 2.3 kW and 6 kW, though the most common slow chargers are rated at 3.6 kW (16A). Charging on a three-pin plug will typically see the car draw 2.3 kW (10A), while the majority of lamp-post chargers are rated at 5.5 kW because of existing infrastructure – some are 3 kW however.
Charging times vary depending on the charging unit and EV being charged, but a full charge on a 3 kW unit will typically take 6-12 hours. Most slow charging units are untethered, meaning that a cable is required to connect the EV with the charge point.
Slow charging is a very common method of charging electric vehicles, used by many owners to charge at home overnight. However, slow units aren’t necessarily restricted to home use, with workplace chargers and public points also able to be found. Because of the longer charging times over fast units, slow public charge points are less common and tend to be older devices.
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While slow charging can be carried out via a three-pin socket using a standard 3-pin socket, because of the higher current demands of EVs and the longer amount of time spent charging, it is strongly recommended that those who need to charge regularly at home or the workplace get a dedicated EV charging unit installed by an accredited installer.
All plug-in EVs can charge using at least one of the above slow connectors using the appropriate cable. Most home units have the same Type 2 inlet as found on public chargers, or tethered with a Type 1 connector where this is suitable for a particular EV.
The choice of connectors depends on the charger type (socket) and the vehicle’s inlet port. On the charger-side, rapid chargers use CHAdeMO, CCS (Combined Charging Standard) or Type 2 connectors. Fast and slow units usually use Type 2, Type 1, Commando, or 3-pin plug outlets.
On the vehicle-side, European EV models (Audi, BMW, Renault, Mercedes, VW and Volvo) tend to have Type 2 inlets and the corresponding CCS rapid standard, while Asian manufacturers (Nissan and Mitsubishi) prefer a Type 1 and CHAdeMO inlet combination.
This doesn’t always apply however, with increasing numbers of Asian manufacturers switching to European standards for cars sold in the region. For example, Hyundai and Kia plug-in models all feature Type 2 inlets, and the pure-electric models use Type 2 CCS. The Nissan Leaf has switched to Type 2 AC charging for its second-generation model, but unusually has retained CHAdeMO for DC charging.
Most EVs are supplied with two cables for slow and fast AC charging; one with a three-pin plug and the other with a Type 2 connector charger-side, and both fitted with a compatible connector for the car’s inlet port. These cables enable an EV to connect to most untethered charge points, while use of tethered units require using the cable with the correct connector type for the vehicle.
Examples include the Nissan Leaf MkI which is typically supplied with a 3-pin-to-Type 1 cable and a Type 2-to-Type 1 cable. The Renault Zoe has a different charging set up and comes with a 3-pin-to-Type 2 and/or Type 2-to-Type 2 cable. For rapid charging, both models use the tethered connectors which are attached to the charging units.
Whenever you waft silently into a electric vehicle charging bay, plug in and then grab a coffee from Costa Coffee, do you ever think about what is going on behind those high frequency whines and massive fridge-like shapes? Do you ever ask how does EV charging work?
Well, let us tell you exactly that.
At GRIDSERVE, we’re proud of our small benevolent army of engineers that are making sure all the EV charging technology at more than 190 EV charging locations are consistently full of renewable energy electrons and working flawlessly, day and night.
Whether you’re using an Electric Forecourt®, Electric Super Hub or Electric Retail Hub, we know speed, ease of use and availability of charging stations are the priority, so we’re doing everything we can to further expand this award-winning ultra-rapid charging network.
When it comes to electric vehicle charging, we tend to have a double act performing all the hard work. Backstage is something called the power cabinet, an anonymous white box that is often hidden from view.
Its job is to safely convert the high voltage, three-phase Alternating Current (AC) that GRIDSERVE receives from the grid into Direct Current (DC) that can directly charge an electric car’s battery. All batteries runs on Direct Current, so you can think of your EV and our electric car charging points in a similar way to your mobile and its charger. Only much bigger.
Why does the grid use AC then, we hear you ask? Partly because AC can be transmitted across long distances without much energy loss, and partly because AC power can be stepped up or down in voltage with simple and low-cost transformers.
One more thing to note about DC vs AC, is that DC charging is for ultra-rapid and rapid chargers whereas AC charging will be used for slower units or home charging points. The AC to DC conversion on slow chargers is done in your car – that’s why it’s slower and less efficient.
Power electronics covered, we move to the main event of how to charge an electric car. The EV charger itself tends to be located at the end of the charging bay, surrounded by safety bollards, clothed in jazzy stickers and featuring a digital screen to display pricing, a contactless payment terminal and one or two EV charging connectors.
In most cases, you’ll find the more popular CCS connector, although we continue to provide CHAdeMO connectors to ensure every electric vehicle on sale can use our network.
A figure expressed in ‘kW’ or kilowatts is writ large at the top of the charging totem and this describes the charging capacity or maximum power: the higher the kW figure, the faster the charge rate will be.
Our latest High Power chargers are 360kW-capable, meaning they can add 100-miles of electric car range in just 5 minutes. Given such high rates of power, the charging cables feature liquid cooling to ensure they can efficiently deliver such a high amount of current to the vehicle. This explains why those cables can often feel quite heavy.
Despite that peak power output, it’s worth remembering that all electric vehicles are controlled by their in-car battery management systems. So, the maximum rate at which anybody can charge is always dictated by the vehicle, rather than the charger.
After removing the connector from its holster and plugging into the vehicle, the charger communicates with the electric vehicle’s battery management system and the GRIDSERVE data centre to facilitate the so-called ‘handshake’ and start the charging session.
Every charger on our network is fitted with fibre optic comms and adheres to the Open Charge Point Protocol (OCPP) cloud platform, the internationally recognised standard for communicating in the EV charging industry.
From processing payments to recognising customer accounts, or even facilitating future services like auto charging, there are so many connected devices within this chain and they all need to be able to understand one another to avoid miscommunication.
Following a series of gateway checks, including protocols for contactless payment, the charging session will start. In real time, the EV charger is then monitoring all communications, calculating how much electricity is needed, at what charging speed and at what cost.
This information is shared with the best-known EV charging apps – so all drivers know the real-time status of this charger – but the data is also analysed by GRIDSERVE Technologies to gather insight regarding this specific charger’s performance, which can then be benchmarked against the rest of the network.
It’s this information that helps to foster a pathway for continuous improvement, which is how we keep improving the EV charging experience for all our customers.
There are a range of factors that impact charging speed – and often it’s not related to the charger itself. Yes, the charging capacity of our fastest units are capable of adding 100 miles of electric car range in just 5 minutes but the possibility of achieving that is dictated by a number of factors:
Contact us to discuss your requirements of Electric Charging Station Manufacturers. Our experienced sales team can help you identify the options that best suit your needs.