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| == Transit traction motors== | == Transit traction motors== | ||
| the driving wheels of a railroad ], electrical ] train (such as a ] or ] train), a ] or an ]. | Transit traction motors powers the driving wheels of a railroad ], electrical ] train (such as a ] or ] train), a ] or an ]. | ||
| Traditionally, these are large ] series-wound motors, usually running on approximately 600 ]s (with a battery pack of 50 batteries of 12 V). The availability of high-powered semiconductors (such as ] and the ]) has now made practical the use of much simpler, higher-reliability ] induction motors (see ]). Synchronous AC motors are also occasionally used, as in the French ]. | Traditionally, these are large ] series-wound motors, usually running on approximately 600 ]s (with a battery pack of 50 batteries of 12 V). The availability of high-powered semiconductors (such as ] and the ]) has now made practical the use of much simpler, higher-reliability ] induction motors (see ]). Synchronous AC motors are also occasionally used, as in the French ]. | ||
Revision as of 20:35, 28 April 2007
A traction motor is a type of electric motor used to power electric vehicles.
Transit traction motors
Transit traction motors powers the driving wheels of a railroad locomotive, electrical multi-unit train (such as a subway or light rail vehicle train), a tram or an electric bus.
Traditionally, these are large DC series-wound motors, usually running on approximately 600 volts (with a battery pack of 50 batteries of 12 V). The availability of high-powered semiconductors (such as thyristors and the IGBT transistor) has now made practical the use of much simpler, higher-reliability AC induction motors (see asynchronous traction motor). Synchronous AC motors are also occasionally used, as in the French TGV.
Before large scale dieselization in 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. It is now standard practice to provide one traction motor driving each axle through a gear drive. Usually, the traction motor is simply suspended between the truck (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. Occasionally, other mounting arrangements are made. In the case of the GG1, two truck-mounted motors drove each axle through a quill drive. The "Bi-Polar" electric locomotives built by General Electric for the Milwaukee Road had gearless motors. The rotating shaft of the motor was also the axle. In the case of the 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 truck (bogie), better dynamics are obtained allowing much-improved high-speed operation.
Because of the high power levels involved, traction motors are almost always cooled using forced air.