. The wheel controls motor power. . This locomotive is on display and not currently in service. An electric locomotive can be supplied with power from •
Rechargeable energy storage systems, such as a battery or
ultracapacitor-powered
mining locomotives. • A stationary source, such as a
third rail or
overhead wire. • A mixture of both. The distinguishing design features of electric locomotives are: • The type of electrical power used,
AC or
DC. • The method of storing (batteries, ultracapacitors), collecting (transmission) electrical power, and/or mixed method. • The means used to couple the
traction motors to the driving wheels (drivers).
Direct and alternating current The most fundamental difference lies in the choice of AC or DC. The earliest systems used DC, as AC was not well understood and insulation material for high voltage lines was not available. DC locomotives typically run at relatively low voltage (600 to 3,000 volts); the equipment is therefore relatively massive because the currents involved are large in order to transmit sufficient power. Power must be supplied at frequent intervals as the high currents result in large transmission system losses. As AC motors were developed, they became the predominant type, particularly on longer routes. High voltages (tens of thousands of volts) are used because this allows the use of low currents;
transmission losses are proportional to the square of the current (e.g. twice the current means four times the loss). Thus, high power can be conducted over long distances on lighter and cheaper wires. Transformers in the locomotives transform this power to a low voltage and high current for the motors. A similar high voltage, low current system could not be employed with direct current locomotives because there is no easy way to do the voltage/current transformation for DC so efficiently as achieved by AC transformers. AC traction still occasionally uses dual overhead wires instead of single-phase lines. The resulting
three-phase current drives
induction motors, which do not have sensitive
commutators and permit easy realisation of a
regenerative brake. Speed is controlled by changing the number of pole pairs in the stator circuit, with acceleration controlled by switching additional resistors in, or out, of the rotor circuit. The two-phase lines are heavy and complicated near switches, where the phases have to cross each other. The system was widely used in northern Italy until 1976 and is still in use on some Swiss
rack railways. The simple feasibility of a fail-safe electric brake is an advantage of the system, while speed control and the two-phase lines are problematic. was the first series locomotive that used
thyristors with DC motors.
Rectifier locomotives, which used AC power transmission and DC motors, were common, though DC commutators had problems both in starting and at low velocities. Today's advanced electric locomotives use brushless
three-phase AC induction motors. These polyphase machines are powered from
GTO-,
IGCT- or
IGBT-based inverters. The cost of electronic devices in a modern locomotive can be up to 50% of the cost of the vehicle. Electric traction allows the use of regenerative braking, in which the motors are used as brakes and become generators that transform the motion of the train into electrical power that is then fed back into the lines. This system is particularly advantageous in mountainous operations, as descending locomotives can produce a large portion of the power required for ascending trains. Most systems have a characteristic voltage and, in the case of AC power, a system frequency. Many locomotives have been equipped to handle multiple voltages and frequencies as systems came to overlap or were upgraded. American
FL9 locomotives were equipped to handle power from two different electrical systems and could also operate as diesel–electrics. While today's systems predominantly operate on AC, many DC systems are still in use – e.g., in
South Africa and the
United Kingdom (750 V and 1,500 V);
Netherlands,
Japan,
Ireland (1,500 V);
Slovenia,
Belgium,
Italy,
Poland,
Russia,
Spain (3,000 V) and
Washington, D.C. (750 V).
Power transmission station near Washington, D.C., electrified at 750 volts. The third rail is at the top of the image, with a white canopy above it. The two lower rails are the ordinary running rails; current from the third rail returns to the power station through these. Electrical circuits require two connections (or for
three phase AC, three connections). From the beginning, the track was used for one side of the circuit. Unlike
model railroads the track normally supplies only one side, the other of the circuit being provided separately.
Overhead lines Railways generally tend to prefer
overhead lines, often called "
catenaries" after the support system used to hold the wire parallel to the ground. Three collection methods are possible: •
Trolley pole: a long flexible pole, which engages the line with a wheel or shoe. •
Bow collector: a frame that holds a long collecting rod against the wire. •
Pantograph: a hinged frame that holds the collecting shoes against the wire in a fixed geometry. Of the three, the pantograph method is best suited for high-speed operation. Some locomotives use both overhead and third rail collection (e.g.
British Rail Class 92). In Europe, the recommended geometry and shape of pantographs are defined by standard EN 50367/IEC 60486
Third rail Mass transit systems and suburban lines often use a third rail instead of overhead wire. It allows for smaller tunnels and lower clearance under bridges, and has advantages for intensive traffic that it is a very sturdy system, not sensitive to snapping overhead wires. Some systems use four rails, especially some lines in the London Underground. One setback for third rail systems is that level crossings become more complex, usually requiring a gap section. The original
Baltimore and Ohio Railroad electrification used a sliding pickup (a
contact shoe or simply the "shoe") in an overhead channel, a system quickly found to be unsatisfactory. It was replaced by a
third rail, in which a pickup rides underneath or on top of a smaller rail parallel to the main track, above ground level. There are multiple pickups on both sides of the locomotive in order to accommodate the breaks in the third rail required by trackwork. This system is preferred in
subways because of the close clearances it affords.
Driving the wheels EP-2 "Bi-polar" electrics During the initial development of railroad electrical propulsion, a number of drive systems were devised to couple the output of the
traction motors to the wheels. Early locomotives often used
jackshaft drives. In this arrangement, the traction motor is mounted within the body of the locomotive and drives the jackshaft through a set of gears. This system was employed because the first traction motors were too large and heavy to mount directly on the axles. Due to the number of mechanical parts involved, frequent maintenance was necessary. The jackshaft drive was abandoned for all but the smallest units when smaller and lighter motors were developed, Several other systems were devised as the electric locomotive matured. The
Buchli drive was a fully spring-loaded system, in which the weight of the driving motors was completely disconnected from the driving wheels. First used in electric locomotives from the 1920s, the Buchli drive was mainly used by the French
SNCF and
Swiss Federal Railways. The
quill drive was also developed about this time and mounted the traction motor above or to the side of the axle and coupled to the axle through a reduction gear and a hollow shaft – the quill – flexibly connected to the driving axle. The
Pennsylvania Railroad GG1 locomotive used a quill drive. Again, as traction motors continued to shrink in size and weight, quill drives gradually fell out of favor in low-speed freight locomotives. In high-speed passenger locomotives used in Europe, the quill drive is still predominant. Another drive was the "
bi-polar" system, in which the motor armature was the axle itself, the frame and field assembly of the motor being attached to the truck (bogie) in a fixed position. The motor had two field poles, which allowed a limited amount of vertical movement of the armature. This system was of limited value since the power output of each motor was limited. The
EP-2 bi-polar electrics used by the
Milwaukee Road compensated for this problem by using a large number of powered axles. Modern freight electric locomotives, like their
Diesel–electric counterparts, almost universally use axle-hung traction motors, with one motor for each powered axle. In this arrangement, one side of the motor housing is supported by plain bearings riding on a ground and polished journal that is integral to the axle. The other side of the housing has a tongue-shaped protuberance that engages a matching slot in the truck (bogie) bolster, its purpose being to act as a torque reaction device, as well as support. Power transfer from the motor to the axle is effected by
spur gearing, in which a
pinion on the motor shaft engages a
bull gear on the axle. Both gears are enclosed in a liquid-tight housing containing lubricating oil. The type of service in which the locomotive is used dictates the gear ratio employed. Numerically high ratios are commonly found on freight units, whereas numerically low ratios are typical of passenger engines.
Wheel arrangements electric locomotive The
Whyte notation system for classifying
steam locomotives is not adequate for describing the variety of electric locomotive arrangements, though the
Pennsylvania Railroad applied
classes to its electric locomotives as if they were steam. For example, the
PRR GG1 class indicates that it is arranged like two
4-6-0 class G locomotives coupled back-to-back.
UIC classification system was typically used for electric locomotives, as it could handle the complex arrangements of powered and unpowered axles and could distinguish between coupled and uncoupled drive systems.
Battery locomotive battery–electric locomotive at
West Ham station used for hauling engineers' trains A battery–electric locomotive (or battery locomotive) is powered by onboard batteries; a kind of
battery electric vehicle. Such locomotives are used where a diesel or conventional electric locomotive would be unsuitable. An example is maintenance trains on underground lines when the electricity supply is turned off. Another use for battery locomotives is in industrial facilities (e.g. explosives factories, oil, and gas
refineries or chemical factories) where a combustion-powered locomotive (i.e.,
steam- or
diesel-powered) could cause a safety issue due to the risks of fire, explosion or fumes in a confined space. Battery locomotives are preferred for
mine railways where gas could be ignited by
trolley-powered units
arcing at the collection shoes, or where excessive
electrical resistance could develop in the supply or return circuits, especially due to poor contact at rail joints, and allow dangerous current leakage into the ground. The first electric locomotive built in 1837 was a battery locomotive. It was built by chemist
Robert Davidson of
Aberdeen in
Scotland, and it was powered by
galvanic cells (batteries). Another early example was at the
Kennecott Copper Mine,
McCarthy, Alaska, wherein 1917 the underground haulage ways were widened to enable working by two battery locomotives of . In 1928, Kennecott Copper ordered four 700-series electric locomotives with onboard batteries. These locomotives weighed and operated on 750 volts
overhead trolley wire with considerable further range whilst running on batteries. The locomotives provided several decades of service using
nickel–iron battery (Edison) technology. The batteries were replaced with
lead-acid batteries, and the locomotives were retired shortly afterward. All four locomotives were donated to museums, but one was scrapped. The others can be seen at the
Boone and Scenic Valley Railroad, Iowa, and at the
Western Railway Museum in Rio Vista, California. The
Toronto Transit Commission previously operated on the
Toronto subway a battery electric locomotive built by
Nippon Sharyo in 1968 and retired in 2009. London Underground regularly operates
battery–electric locomotives for general maintenance work. , battery locomotives with 7 and 14 MWh energy capacity have been ordered by rail lines and are under development. In 2026, two classes of battery locomotives are in testing in Western Australian mining railways, the
Wabtec FLXDrive for
BHP and another class built by
Progress Rail for
Fortescue. In December 2024, the
Grand Canyon Railway, which operates passenger excursion trains to the
Grand Canyon National Park, announced that they would rebuild one of their
EMD F40PHs as a battery-electric locomotive to reduce diesel emissions and maintenance costs. In January 2026,
Cuyahoga Valley Scenic Railroad, which operates excursions through the
Cuyahoga Valley National Park, similarly announced that they would rebuild two of their
MLW FPA-4s as battery-electric units.
Supercapacitor power storage In 2020,
Zhuzhou Electric Locomotive Company, manufacturers of stored electrical power systems using
supercapacitors initially developed for use in
trams, announced that they were extending their product line to include locomotives. ==Electric locomotives around the world==