The autobahn is empty and you’re driving 200 kmh, until a small delivery van changes lanes to pass a truck. No problem – you’re maintaining a safe distance and slow down to 100 kmh. But a great deal of energy is consumed in the blink of an eye, as vehicles with an internal combustion engine convert kinetic energy into heat when the brakes are applied, which they’re unable to use. Electric vehicles, on the other hand, can recover a large portion of this energy, using the electric machines as generators when slowing down and ­storing the power generated in the ­battery.

For example, the Porsche Taycan can use a significant amount of the ­braking energy for propulsion, which is referred to as recuperation, based on the Latin ­recuperare. Recuperation has established itself as a technical term. Kinetic braking energy increases twice as fast as speed – double the speed means four times the recuperation. When ­braking from 100 kmh, the Taycan ­generates four times as much energy as when braking from 50 kmh. This ­recuperation and the propulsion itself both play a key role in the efficiency of electric vehicles.

How does the Taycan do that?

“We incorporate the electric motors we produce in Zuffenhausen into the brake system for the purpose of energy recovery,” explains Ingo Albers, Head of Chassis Development at the Porsche development center in Weissach. “Electric motors can generally be controlled in four-quadrant operation.” In other words, an electric motor can work with both the rotation speed and torque running in the same – positive – direction. But each electric motor can also function as a generator, in which case the motor continues to turn in the same direction, but is now powered by the wheels rather than powering them itself. It ­generates electrical energy, rather than consuming it. And because it takes a lot of energy to power the motor and thus turn the rotor against the ­magnetic ­resistance, this negative torque can be used to brake the vehicle.

The control units and power electronics of the electric motors in the Taycan are therefore intelligently connected with the controls and logics of the brake control system. The conventional hydraulic wheel brake and electric motors can slow down the vehicle together. The experts in Weissach have developed a complex recuperation strategy. Within milliseconds, the electronics decide what percentage of the braking will be electric and what percentage will be hydraulic. While the driver cannot feel the difference, they can see it in the power meter in the instrument cluster. 

Around 90 percent of everyday braking is 100 percent electric, allowing the Taycan to recover energy. “But in extreme situations, such as full braking from a top speed in a fully loaded Taycan, a maximum braking capacity of more than two megawatts must be applied,” says Albers. “The electric powertrain cannot do that alone. The conventional wheel brake is then applied to a higher degree.” It may also activate because the battery is already full and can no longer recharge through recuperation. Just in case – take, for instance, downhill driving – the hydraulic wheel brake is designed for high performance. Thanks to the design of the electric motors and the electronics in conjunction with Porsche’s signature intelligent control, the Taycan can ­recuperate with up to 290 kilowatts. “That’s at the ­absolute top of the field,” says Albers. “And we plan to increase this value.”

Some car manufacturers have the electric drive’s recuperation system activate automatically the moment the driver removes their foot from the gas pedal, which is referred to as one-pedal driving. “We made the decision to go a different route with the Taycan,” says Albers. “You apply the brakes to slow down, which is a learned behavior and it’s authentic. The driver receives consistent, predictable feedback. We also offer full integration of systems such as ABS and PSM.” ­Technically speaking, it would be much easier to apply the ­electric motor braking to the gas pedal, rather than integrating it into the brake ­system. “But we incor­porated ­limited recuperation into the gas pedal, which the driver ­perceives to be ­efficient, smooth coasting particularly in rural areas,” explains Ingo Albers. 

In brief

Porsche will always be Porsche – in continuous optimization. We even defined our own path when developing the first all-electric sports car in Zuffenhausen – always with the goal of maximum efficiency. With this clever strategy in the background, the Taycan secures around one-third of its range with the recovery of brake energy, i.e. recuperation. 

Info

Text first published in Christophorus Magazine, No. 403.

Author: Heike Hientzsch

Photographers: Rafael Krötz, Porsche

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Consumption data

Taycan Turbo GT

WLTP*
  • 0 g/km
  • 21,6 – 20,7 kWh/100 km
  • 528 – 554 km

Taycan Turbo GT

Consumo di carburante / Emissioni
emissioni CO₂ combinato (WLTP) 0 g/km
consumo elettrico combinato (WLTP) 21,6 – 20,7 kWh/100 km
Gamma elettrica combinata (WLTP) 528 – 554 km
Gamma elettrica in aree urbane (WLTP) 638 – 677 km
Classe di efficienza: B

Taycan Turbo GT with Weissach package

WLTP*
  • 0 g/km
  • 21,3 – 20,6 kWh/100 km
  • 538 – 555 km

Taycan Turbo GT with Weissach package

Consumo di carburante / Emissioni
emissioni CO₂ combinato (WLTP) 0 g/km
consumo elettrico combinato (WLTP) 21,3 – 20,6 kWh/100 km
Gamma elettrica combinata (WLTP) 538 – 555 km
Gamma elettrica in aree urbane (WLTP) 673 – 699 km
Classe di efficienza: B