Traction motor refers to an electric motor providing the primary rotational torque of a machine, usually for conversion into linear motion (traction).
Traction motors are used in electrically powered rail vehicles such as electric multiple units and electric locomotives, other electric vehicles such as electric milk floats, elevators and conveyors as well as vehicles with electrical transmission systems such as diesel-electric, electric hybrid vehicles and battery electric vehicles. Additionally, electric motors in other products (such as the main motor in a washing machine) are described as traction motors
Traditionally, these were DC series-wound motors, usually running on
approximately 600 volts. The availability of high-powered semiconductors (such
as thyristors
and the IGBT) has now made
practical the use of much simpler, higher-reliability AC induction motors known
as asynchronous traction motors. Synchronous AC motors are also occasionally
used, as in the French TGV.
Before the mid-20th century, a single large motor was often used to drive
multiple driving wheels
through connecting rods that were very
similar to those used on steam locomotives. Examples are the Pennsylvania Railroad DD1, the PRR L5 and the various Swiss
Crocodiles. It is now standard practice to provide one traction motor
driving each axle through a gear drive.
Usually, the traction motor is three-point suspended between the bogie frame and the driven axle; this is
referred to as a "nose-suspended traction motor". The problem with such an
arrangement is that a portion of the motor's weight is unsprung, increasing
forces on the track. In the case of the famous Pennsylvania Railroad GG1, two bogie-mounted motors drove
each axle through a quill
drive. The "Bi-Polar" electric locomotives built by General Electric for
the Milwaukee Road had direct drive motors. The
rotating shaft of the motor was also the axle for the wheels. In the case of
French TGV power units, a motor mounted to the power unit’s frame drives each
axle; a "tripod" drive allows a small amount of flexibility in the drive train
allowing the trucks (bogies) to pivot. By mounting the relatively heavy
traction motor directly to the power unit rather than to the bogie, better
dynamics are obtained allowing better high-speed operation.
The DC motor was the mainstay of electric traction drives on both electric
and diesel-electric locomotives and street-cars/trams for many years. It
consists of two parts, a rotating armature and fixed field windings surrounding
the rotating armature mounted around a shaft. The fixed field windings consist
of tightly wound coils of wire fitted inside the motor case. The armature is
another set of coils wound round a central shaft and is connected to the field
windings through "brushes" which are spring loaded contacts pressing against an
extension of the armature called the commutator. The commutator collects all the
terminations of the armature coils and distributes them in a circular pattern to
allow the correct sequence of current flow. When the armature and the field
windings are connected in series, the whole motor is referred to as
"series-wound". A series-wound DC motor has a low resistance field and armature
circuit. Because of this, when voltage is applied to it, the current is high.
(Ohms Law: current = voltage/resistance). The advantage of high current is that
the magnetic fields inside the motor are strong, producing high torque (turning
force), so it is ideal for starting a train. The disadvantage is that the
current flowing into the motor has to be limited, otherwise the supply could be
overloaded and/or the motor and its cabling could be damaged. At best, the
torque would exceed the adhesion and the driving wheels would slip.
Traditionally, resistors were used to limit the initial current.
As the DC motor starts to turn, the interaction of the magnetic fields inside
causes it to generate a voltage internally. This "back-EMF" (electromagnetic
force) opposes the applied voltage and the current that flows is governed by the
difference between the two. As the motor speeds up, the internally generated
voltage rises, the resultant EMF falls, less current passes through the motor
and the torque drops. The motor naturally stops accelerating when the drag of
the train matches the torque produced by the motors. To continue accelerating
the train, series resistors are switched out steps by step, each step increasing
the effective voltage and thus the current and torque for a little bit longer
until the motor catches up. This can be heard and felt in older DC trains as a
series of clunks under the floor, each accompanied by a jerk of acceleration as
the torque suddenly increases in response to the new surge of current. When no
resistors are left in the circuit, full line voltage is applied directly to the
motor. The train's speed remains constant at the point where the torque of the
motor, governed by the effective voltage, equals the drag - sometimes referred
to as balancing speed. If the train starts to climb an incline, the speed
reduces because drag is greater than torque and the reduction in speed causes
the back-EMF to fall and thus the effective voltage to rise - until the current
through the motor produces enough torque to match the new drag.
On an electric train, the train driver originally had to control the cutting
out of resistance manually, but by 1914, automatic acceleration was being used.
This was achieved by an accelerating relay (often called a "notching relay") in
the motor circuit which monitored the fall of current as each step of resistance
was cut out. All the driver had to do was select low, medium or full speed
(called "shunt", "series" and "parallel" from the way the motors were connected
in the resistance circuit) and the automatic equipment would do the rest.
Traction motors are used in electrically powered rail vehicles such as electric multiple units and electric locomotives, other electric vehicles such as electric milk floats, elevators and conveyors as well as vehicles with electrical transmission systems such as diesel-electric, electric hybrid vehicles and battery electric vehicles. Additionally, electric motors in other products (such as the main motor in a washing machine) are described as traction motors
Usually, the traction motor is three-point suspended between the bogie frame and the driven axle; this is
referred to as a "nose-suspended traction motor". The problem with such an
arrangement is that a portion of the motor's weight is unsprung, increasing
forces on the track. In the case of the famous Pennsylvania Railroad GG1, two bogie-mounted motors drove
each axle through a quill
drive. The "Bi-Polar" electric locomotives built by General Electric for
the Milwaukee Road had direct drive motors. The
rotating shaft of the motor was also the axle for the wheels. In the case of
French TGV power units, a motor mounted to the power unit’s frame drives each
axle; a "tripod" drive allows a small amount of flexibility in the drive train
allowing the trucks (bogies) to pivot. By mounting the relatively heavy
traction motor directly to the power unit rather than to the bogie, better
dynamics are obtained allowing better high-speed operation.
The DC motor was the mainstay of electric traction drives on both electric
and diesel-electric locomotives and street-cars/trams for many years. It
consists of two parts, a rotating armature and fixed field windings surrounding
the rotating armature mounted around a shaft. The fixed field windings consist
of tightly wound coils of wire fitted inside the motor case. The armature is
another set of coils wound round a central shaft and is connected to the field
windings through "brushes" which are spring loaded contacts pressing against an
extension of the armature called the commutator. The commutator collects all the
terminations of the armature coils and distributes them in a circular pattern to
allow the correct sequence of current flow. When the armature and the field
windings are connected in series, the whole motor is referred to as
"series-wound". A series-wound DC motor has a low resistance field and armature
circuit. Because of this, when voltage is applied to it, the current is high.
(Ohms Law: current = voltage/resistance). The advantage of high current is that
the magnetic fields inside the motor are strong, producing high torque (turning
force), so it is ideal for starting a train. The disadvantage is that the
current flowing into the motor has to be limited, otherwise the supply could be
overloaded and/or the motor and its cabling could be damaged. At best, the
torque would exceed the adhesion and the driving wheels would slip.
Traditionally, resistors were used to limit the initial current.
As the DC motor starts to turn, the interaction of the magnetic fields inside
causes it to generate a voltage internally. This "back-EMF" (electromagnetic
force) opposes the applied voltage and the current that flows is governed by the
difference between the two. As the motor speeds up, the internally generated
voltage rises, the resultant EMF falls, less current passes through the motor
and the torque drops. The motor naturally stops accelerating when the drag of
the train matches the torque produced by the motors. To continue accelerating
the train, series resistors are switched out steps by step, each step increasing
the effective voltage and thus the current and torque for a little bit longer
until the motor catches up. This can be heard and felt in older DC trains as a
series of clunks under the floor, each accompanied by a jerk of acceleration as
the torque suddenly increases in response to the new surge of current. When no
resistors are left in the circuit, full line voltage is applied directly to the
motor. The train's speed remains constant at the point where the torque of the
motor, governed by the effective voltage, equals the drag - sometimes referred
to as balancing speed. If the train starts to climb an incline, the speed
reduces because drag is greater than torque and the reduction in speed causes
the back-EMF to fall and thus the effective voltage to rise - until the current
through the motor produces enough torque to match the new drag.
On an electric train, the train driver originally had to control the cutting
out of resistance manually, but by 1914, automatic acceleration was being used.
This was achieved by an accelerating relay (often called a "notching relay") in
the motor circuit which monitored the fall of current as each step of resistance
was cut out. All the driver had to do was select low, medium or full speed
(called "shunt", "series" and "parallel" from the way the motors were connected
in the resistance circuit) and the automatic equipment would do the rest.
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