On vehicles with a hybrid drive system, an internal combustion engine is combined with one or more electric motors. The electric motor converts electric energy into mechanical force and uses it to drive the vehicle.
Electric motors generally fall into one of the following categories:
The type of motor now almost always used in modern electric vehicles is the three-phase motor.
In both direct-current motors and three-phase motors, the torque is generated by the attraction force between two magnetic fields. One of these magnetic fields is generated electromagnetically. One magnet is in a stationary position and is called a “stator”. The other is a rotating component and is called the “rotor”. It is also possible for both magnetic fields to be generated electromagnetically. For example, the rotor can be magnetised by what is known as an excitation winding (special coils/wire windings that generate a magnetic field when an electric current passes through them).
In a direct-current motor, the north and south poles of the stator and rotor attract each other, which causes the motor to rotate. The rotational movement is continued through pole reversal, whereby the north and south poles repel each other. After another half turn there is another pole reversal, and the process is repeated. Direct-current motors also have certain disadvantages: the speed, power density and efficiency are lower than on a three-phase motor, and the brushes require a lot of maintenance.
A three-phase motor has at least three electromagnetic coils offset by 120°. If each of these three coils is supplied with a so-called line voltage phase from the three-phase system, then a magnetic field is generated in each coil. These magnetic fields are offset in intervals of a third in the time cycle. A rotating magnetic field is formed from the individual magnetic fields of the coils. If a rotating magnet (rotor) is put into the centre of this magnetic field, the rotary field causes the magnet to turn. Three-phase motors can be designed as both synchronous and asynchronous motors.
The difference between a synchronous motor and an asynchronous motor is in how the rotor works. With an asynchronous motor, the rotor follows the stator rotary field with a delay, so asynchronously. With a synchronous motor, the rotor follows the specified frequency and the magnetic rotary field in the stator in sync.
Electric motors have a broad speed and torque range, and this makes them almost ideal – at least in this respect – as vehicle motors. This is why with most electric motors in electric cars, you don’t need multiple gears or a manual transmission. They also offer high efficiency. Efficiency is the ratio between the provided energy and the energy that is available for propulsion. Electric motors achieve an efficiency of around 80 to 90 percent, petrol engines around 33 percent and diesel engines around 45 percent. In addition, the maximum torque of an electric motor is already available at a standstill and the motors make hardly any noise. Other advantages include their simple, compact design, their low weight, being low-maintenance, and the ability to use the motor as a generator during the deceleration phase.
Given that electric motors don’t emit any emissions, at least at a local level, they are considered more environmentally friendly than internal combustion engines. However, the production of the electrical power itself may produce harmful substances. The most environmentally friendly solution is when 100% renewable energy sources are used to generate power.