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Third rail

The third rail is a method of supplying electric power to railway trains via a rigid conductor rail positioned alongside or between the two running rails of the track, from which the train collects current through a sliding metal contact known as a shoe. This system delivers direct current (DC) at common voltages of 600 V or 750 V, enabling efficient operation in constrained environments such as tunnels and urban areas. The term "third rail" originated in the 1860s amid the development of early subway systems, referring to the additional rail that powers trains alongside the two primary running rails. Commercial implementation began around 1900, initially for underground and metro railways, with mainline applications following shortly after, such as the Southern Region in the UK starting in 1915. Today, third rail systems power approximately one-third of the UK's weekday passenger services, particularly in the densely populated South East, supporting trains up to 12 carriages long and speeds of 100 mph (160 km/h). Globally, third rail electrification is prevalent in urban transit networks, including subways and commuter rails in cities like London, New York, and Buenos Aires, due to its compatibility with frequent stops and shorter distances between stations. Key advantages include lower installation and maintenance costs compared to overhead catenary systems, reduced visual impact in urban settings, and greater resilience to wind-related disruptions. However, notable drawbacks encompass significant safety hazards from the exposed high-voltage conductor, which can cause electrocution or severe injury upon contact; limitations on maximum speeds (generally below 100 mph due to mechanical wear and power gaps); vulnerability to snow, ice, or flooding; and less suitability for longer or heavier freight trains due to high current requirements, power losses, and infrastructure demands. Safety measures, such as protective covers, insulated sections, and public awareness campaigns, are essential to mitigate risks to trespassers and maintenance workers.

Description

Basic Principles

The third rail is an energized conductor rail positioned alongside the two running rails of a to supply (DC) power to electric trains. This system enables electric locomotives and multiple units to draw directly from the track without relying on overhead wires, facilitating operation in environments where systems may be impractical, such as tunnels or urban areas. Typically, the voltage supplied is in the range of 600-1200 V DC, with 750 V DC being common in many systems, which is converted on the train into motive power for traction motors. In a standard third rail setup, the consists of two parallel running that support and guide the wheels, with the third rail mounted adjacent to one of them, often at a height of about 3-4 inches (76-100 mm) above the top of one of the running rails and insulated from the running rails. Power is collected by sliding contact shoes attached to the of the , which maintain continuous electrical as the moves. This ground-level simplifies in confined spaces compared to elevated overhead lines. Historically, the third rail emerged as a practical alternative to overhead catenary systems for delivering power at track level and was first implemented in urban subway networks around 1900, marking a key advancement in electric rail transit for dense city environments.

Key Components

The third rail, also known as the conductor rail, is typically constructed from high-strength steel to provide durability and structural integrity under the mechanical stresses of train passage. Many modern systems employ composite profiles, such as aluminum-stainless steel designs, where an aluminum core enhances electrical conductivity while a stainless steel outer layer offers superior wear resistance on the contact surface. These rails feature specific cross-sectional profiles, often rectangular or bar-shaped with a flat or slightly elevated top contact surface, differing from the bullhead or flat-bottom profiles used in running rails; common sections include weights around 100-150 lb/yd to balance conductivity and robustness. To maintain precise positioning and electrical isolation, the third rail is supported by insulators, typically made from cycloaliphatic resin for UV and resistance, preventing unintended contact with the or running rails. These insulators are mounted on brackets or stanchions attached to the track sleepers, spaced at regular intervals (e.g., every 3-5 meters) to accommodate and vertical loads. Electrical bonds, such as signal bonds or compression connectors, ensure continuity across rail joints and expansion gaps, minimizing voltage drops while avoiding short circuits. On the train side, power collection occurs via contact shoes, or shoegear, which are sliding assemblies mounted on the bogies and pressed against the third rail's top surface. These shoes are commonly made from carbon-based materials like for low and consistent , though metal options such as or are used in some designs for higher current capacity; a supporting carrier protects the contact element from impacts and deflection. Wear patterns on contact shoes manifest as gradual from sliding , often accelerated in high-speed or frequent-service operations, necessitating regular inspection and replacement to maintain intimate contact and prevent arcing. In third rail systems, the two running rails occasionally serve as return paths for the traction current, distributing it back to the substation alongside the third rail supply. To enable safe operation of track circuit signaling, impedance bonds are installed across the running rails at insulated joints, providing low impedance for DC traction currents (typically 750 V DC) to flow unimpeded while presenting high impedance to AC signaling frequencies, thus preventing interference with train detection.

Advantages and Disadvantages

Operational Benefits

Third rail systems provide a lower visual impact than overhead wire , blending more seamlessly into landscapes without prominent overhead structures. This aesthetic advantage is particularly beneficial in densely populated cities, where preserving the visual is a priority for community acceptance and . Additionally, third rail eliminates the need for overhead , enabling easier tunnel clearance and more straightforward construction in subterranean s common to systems. These features make third rail ideal for railways, where space constraints and integration with existing demand compact solutions. Maintenance of third rail is simpler in enclosed spaces like tunnels, as the system lacks elevated components that require elevated access platforms or aerial work, allowing ground-level inspections and repairs with standard equipment. The design also avoids the complexities of maintenance associated with overhead systems, streamlining routine operations and reducing downtime in confined urban settings. Furthermore, the absence of overhead wires and pantographs minimizes aerodynamic drag on trains at higher speeds, contributing to improved during and sustained travel. Third rail offers cost savings in initial for and metros, particularly in dense urban areas, where overhead systems require additional structural supports and clearances that inflate expenses. These savings arise from simpler ground-level construction without the need for elevated infrastructure, making third rail a more economical choice for underground or low-clearance routes. The London demonstrates the operational efficiency of third rail in high-frequency services, powering extensive networks with trains operating at intervals as short as 90 seconds during peak hours, supporting over 1.3 billion passenger journeys annually through reliable, uninterrupted power delivery. This setup enables high-capacity urban transit with capabilities that enhance overall system efficiency, particularly in stop-start operations.

Technical Limitations

Third rail systems are particularly susceptible to weather-related disruptions, especially in cold climates where snow and ice accumulation on the conductor rail can insulate it and reduce electrical conductivity, leading to power loss and service interruptions. To mitigate this, operators often employ measures such as sleet scrapers on train shoes, deicer fluid distribution from railcars, or trackside heating elements; for instance, the Chicago Transit Authority (CTA) equips its railcars with scrapers and deicers to clear accumulations on the third rail during winter operations. These interventions, while effective, add to maintenance costs and complexity, particularly in regions with frequent freeze-thaw cycles. Although third rail electrification avoids the visual clutter of overhead wires and poles, the exposed conductor rail itself can present aesthetic challenges in scenic or environmentally sensitive areas, where the metallic rail along the trackbed may detract from natural landscapes despite being less obtrusive overall. Operational speeds on third rail networks are generally limited to below 100 mph (160 km/h) for safety and performance reasons, as the sliding contact mechanism struggles with stability at higher velocities, and the typical DC voltages of 600–750 V constrain power delivery for acceleration and sustained high-speed running. Recent research explores enhancements like advanced collector shoes to support speeds up to 120 km/h (75 mph) in select applications. This voltage limitation also restricts the feasibility of third rail for very long-distance routes, necessitating more frequent substations to maintain adequate power supply and increasing infrastructure demands compared to overhead systems that support higher voltages over extended distances. Gaps in the third rail supply, often required at stations, level crossings, or transitions to other electrification types, force trains to coast unpowered or rely on onboard batteries, which can compromise reliability and schedule adherence if is insufficient to bridge longer interruptions. While batteries enable seamless operation across short gaps up to 300 meters, extended or unplanned discontinuities may still result in delays, highlighting a key constraint in system design for consistent performance.

Safety Considerations

The third rail, typically energized at 750 volts () in systems like those in the , presents significant hazards due to its exposed position along the track, allowing unintended contact that can drive lethal currents through the . Currents exceeding 100 milliamperes can cause and death, and the high amperage available from the rail—often thousands of amperes—amplifies this risk even with relatively , as body resistance drops under wet or sweaty conditions. Historical incidents underscore these dangers; for instance, a 2016 case in the UK involved a man who fell onto a live third rail, suffering multiple cardiac arrests and severe burns requiring near-amputation of his legs. In the United States, a review of third rail contacts at 600 V identified 16 cases over several years, including seven among workers where unintentional tool or hand contact led to deep burns, amputations, and long-term cardiac complications. Trespassers face acute risks from accidental contact, with surveys indicating widespread underestimation of the threat—38% of respondents believed electrocution from rails would not cause serious injury—contributing to incidents like the 2025 electrocution of a young woman in Kent, UK, after she was drawn to the live rail. First responders and maintenance personnel are also vulnerable during emergencies or repairs, where proximity to the energized rail heightens exposure; in the US, such risks are addressed through mandatory training under Federal Railroad Administration (FRA) standards in 49 CFR Part 214, which require certification in hazard recognition, safe work practices, and emergency response near electrified tracks. Additionally, NFPA 130 provides life safety protocols for fixed guideway transit systems, emphasizing electrical isolation and personal protective equipment to protect workers and responders. Mitigation strategies focus on physical barriers and procedural safeguards to prevent contact. Rail covers and shields, often made of insulating materials, encase the third rail to reduce exposure during normal operations and , while platform edge doors or gates at stations fully separate passengers from the track area, preventing falls onto live rails. For , depowering is critical; in the UK, Network Rail's Safer Faster Isolation (SFI) programme, implemented progressively since the early 2000s, uses remote switches and negative short-circuiting devices to isolate sections of the conductor rail, minimizing the time workers spend in hazardous zones and reducing shock risks. Compared to overhead , third rail systems exhibit higher fatality rates due to the rail's ground-level accessibility, with data from the Office of Rail and Road indicating third rail accounts for eight times the equivalent fatalities of 25 kV overhead lines despite comprising only half the electrified mileage. Modern safeguards have lowered these risks; in the , post-2000 initiatives like SFI and enhanced trespasser education have contributed to a 20% reduction in rail-related incidents, including electrocutions, according to reports.

Technical Design

Power Delivery and Contact

The power delivery in third rail systems occurs through direct sliding contact between the train's collector shoes and the energized conductor rail, enabling continuous transfer of direct current (DC) to the train's traction motors. The collector shoes, mounted on the train's undercarriage, are designed to slide along the rail's surface while maintaining intimate electrical and mechanical contact. This contact is ensured by spring-loaded mechanisms, typically using coil springs that apply consistent downward pressure—often between 50 and 150 N depending on the system—to compensate for track irregularities, vibrations, and relative motion between the train and rail. Such designs prevent intermittent contact loss, which could disrupt power supply or cause arcing. Electrical considerations in power delivery are dominated by the inherent resistance of the conductor rail, which leads to voltage drops along its length according to Ohm's law, V = IR, where V is the voltage drop, I is the traction current (often exceeding 5,000 A during acceleration), and R is the rail's longitudinal resistance (typically 0.01–0.05 Ω/km for steel or aluminum rails). These drops can reduce available voltage at the train from nominal levels (e.g., 750 V DC) by 10–15% or more over extended distances, potentially limiting train performance and regenerative braking efficiency. To mitigate this, power supply segments between traction substations are limited to approximately 1–2 km, allowing substations to boost voltage and maintain a minimum of 500–550 V at the farthest point under full load. For high-speed applications exceeding 160 km/h, traditional flexible third rails face challenges with contact stability due to aerodynamic forces and vibrations, prompting the use of alternative rigid conductor technologies. Rigid conductors, often aluminum profiles fixed directly to the or walls, provide a stiffer structure that supports higher current densities and reduces wear at elevated speeds, as seen in certain urban extensions. These differ from conventional rails by eliminating joints and flexing, though they are more common in confined spaces like s rather than open high-speed lines. Insulation and arcing prevention are integral to safe shoe-rail interaction, as momentary contact losses can generate electric arcs that erode both the rail and shoe. The conductor rail is insulated from the ground and running rails using non-conductive covers made of fiberglass-reinforced plastic or , with creepage distances of at least 100 mm to prevent . Collector shoes employ low-friction materials like sintered carbon or copper-impregnated , which exhibit high electrical while minimizing sparking through self-lubricating properties and thermal resistance up to 1,500°C. Spring tension and shoe geometry further reduce arcing by limiting , though residual arcing at rail joints or under high loads contributes to gradual material erosion, necessitating periodic inspections.

Return Current Mechanisms

In third rail systems, the return current from the traction motors flows back to the substations primarily through the running rails, which serve as the negative in the due to their economic advantages and existing . This setup completes the electrical without requiring additional dedicated return conductors, allowing the power supplied via the third rail to be efficiently recycled at the substation. To balance the current distribution and minimize voltage drops, cross-bonding connects the running rails at regular intervals, enabling the traction current to be shared across multiple rails—typically forming paths between up to four rails in a double-track . These bonds, often implemented with welded or bolted connections, reduce the effective resistance of the return path and ensure even current loading, particularly in sections with high traction demand. Impedance bonds are employed at track circuit boundaries to separate the low-frequency DC traction return currents from the higher-frequency AC signaling currents, preventing that could disrupt train detection systems. These devices, consisting of center-tapped coils with to AC but low to DC, allow traction currents to pass through while blocking signaling currents, thereby maintaining across insulated rail joints. Substations connect directly to the running rails to collect the return currents, while grounding systems at these locations and along the track absorb stray currents that leak into the due to imperfect , mitigating electrolytic of nearby metallic structures such as pipelines and building foundations. Effective grounding, often involving buried anodes or direct rail-to-earth connections, directs these stray currents back to the substation negative bus, reducing rates and ensuring system longevity. In long sections, the cumulative of the running rails can lead to significant voltage drops and efficiency losses, with studies indicating approximately 16-21% of input power lost as line losses in 750V systems, with a portion dissipated as in densely loaded setups due to the rails' longitudinal impedance. This challenge is exacerbated by frequent stops and high currents in metropolitan networks, necessitating closer substation spacing to maintain acceptable power delivery.

Gaps and Transitions

In third rail systems, interruptions known as gaps occur at crossovers, depots, and voltage points to facilitate switching, , or electrical sectioning. These gaps typically range from short dead sections of about 3-15 meters at crossovers and insulators to longer breaks up to 100-200 meters in some configurations, requiring to maintain for coasting through the unpowered zone without stalling. Multiple collector shoes distributed along the length help bridge shorter gaps by ensuring continuous contact with adjacent powered segments, while for extended interruptions, modern may employ onboard batteries to sustain auxiliary systems or briefly. Transition zones between third rail and overhead electrification incorporate neutral sections to prevent arcing between differing voltage systems, often DC third rail and AC overhead lines. Trains in such zones use dual-mode equipment with collector shoes for third rail and pantographs for overhead, switching power sources via manual controls operated by the driver or automatic devices like vacuum circuit breakers triggered by trackside markers or position sensors. Manually operated hook switches isolate third rail sections during the handover, while automated systems employ computer vision to detect visual cues and execute seamless transitions without driver intervention. In UK third rail to overhead line transitions, dead sections are designed to minimize coasting requirements, typically around 50-100 meters. Design standards for third rail gaps emphasize safety and reliability, specifying minimum lengths to avoid unintended contact between sections and maximum bridgeable distances based on train performance. Warning systems include trackside , illuminated indicators, and in-cab alerts that notify drivers of approaching gaps, instructing them to accelerate beforehand or maintain specific speeds for safe passage. Historically, third rail transitions evolved from fully manual operations to increasingly automated processes, particularly in dense urban networks like the New York Subway. Early implementations in the 1904 IRT subway relied on motormen visually identifying gaps at crossovers or depots and manually coasting through using momentum, supported by basic semaphore signals. By the mid-20th century, the system incorporated with fixed wayside indicators to warn of power interruptions, reducing reliance on driver judgment and enabling smoother handling of section transitions without manual intervention beyond adjustments.

Variations and Implementations

Mixed Electrification Systems

Mixed electrification systems integrate third rail and power supplies along a single route, primarily to bridge urban sections favoring third rail for its compact design in confined spaces like tunnels and platforms with rural or high-speed segments benefiting from overhead lines' capacity for higher voltages and reduced visual impact. This approach allows seamless operation without full conversion of existing , enabling dual- or multi-voltage trains to handle transitions efficiently. In the , the (HS1) route, serving services, employs 25 kV AC overhead electrification for its main alignment but incorporates 750 V DC third rail at key connections, such as to the and Ashford domestic lines, to interface with the legacy southern network. Similarly, the core network utilizes dual-voltage capable of operating on 25 kV AC overhead north of Farringdon and switching to 750 V DC third rail southbound, supporting cross-London services without interruption. The exemplifies transitional mixed systems, having converted much of its original 750 V DC third rail to 25 kV AC overhead while maintaining compatibility at junctions for freight and passenger interchanges. In the , the included hybrid segments on lines such as route 51 (discontinued in 2019), where trains transitioned from 750 V DC third rail in tunnel sections to 600 V DC overhead wires on surface alignments, using specialized vehicles to maintain service continuity. These transitions occur at designated gaps, where pantographs raise or collector shoes engage, minimizing as explored further in the Gaps and Transitions section.

Non-Standard Voltages

While most third rail systems operate at 600-750 V DC to balance safety, efficiency, and infrastructure costs, several urban rail networks employ higher DC voltages to support greater power demands in dense or extended metro environments. For instance, the uses 1,200 V DC third rail, allowing for improved energy transmission and capacity in its regional network. These elevated voltages reduce current requirements and associated resistive losses, though they necessitate enhanced on the rail and contact shoes to prevent arcing. Historical examples include the in , which operated at 1,200 V DC side-contact third rail until its conversion to overhead in 1991. Such configurations highlight adaptations for specific operational needs, but they increase engineering complexity, including reinforced creepage distances on insulators to mitigate risks under humid or contaminated conditions. Although (AC) third rail systems have been explored in early 20th-century experiments, such as preliminary trials around 660 V AC in suburban railways, they did not achieve widespread adoption due to challenges with AC motor synchronization and higher insulation needs at the rail level. These historical efforts, often limited to short test sections, underscored the preference for DC in third rail designs for simpler traction control. In applications, third rail voltages occasionally exceed 1,000 V DC, as seen in some private freight sidings, but examples remain scarce and typically customized for low-speed, controlled environments to address heightened safety protocols. Recent metro expansions in have considered voltage optimizations for third rail efficiency, though most post-2020 projects adhere to 750 V standards; for example, upgrades in India's incorporate advanced like aluminum third rails to reduce losses at conventional voltages, indirectly supporting potential future escalations. Challenges with non-standard voltages persist, particularly in retrofitting older systems, where equipment compatibility requires dual-voltage converters and rigorous testing to avoid disruptions. Overall, these variations demonstrate third rail's flexibility beyond the norm, prioritizing site-specific power delivery while adhering to international safety standards like those from the .

Simultaneous Use with Overhead Lines

Dual-contact systems enable trains to operate using both third rail collector shoes and pantographs, providing flexibility for routes with varying or redundancy in critical operations. Historical examples include the North Eastern Railway's ES1 class locomotives, built in 1905 by , which featured bow collectors for overhead wires in open yards and third rail shoes for sections on the Newcastle Quayside to address clearance constraints. Technical setups for concurrent supply demand synchronized DC voltages—typically 600-750 V for both systems—to minimize arcing or faults during transitions, with onboard controls or insulators preventing unintended dual contact. Both infrastructures run parallel along tracks in select areas, allowing trains to draw from one source while the other remains energized for adjacent operations, though simultaneous dual collection is prohibited to avoid electrical interference. The U.S. illustrates such configurations in transition zones, where overhead and third rail coexist to support mixed fleets without service interruptions. These arrangements offer redundancy against single-system failures, such as damage from weather or third rail icing, ensuring continuous power in maintenance yards where diverse requires versatile access. For example, U.S. facilities often employ systems to test or service locomotives from third rail urban networks alongside overhead regional lines, enhancing operational resilience. Limitations stem from the added demands, including reinforced pantograph-shoe and expanded substation capacity, which elevate costs by 20-30% over single-mode setups and complicate signaling integration. Consequently, simultaneous use remains rare in passenger service, confined mostly to yards or short segments like preserved ES1 operations.

Global Applications

Europe

In Europe, third rail is predominantly utilized in dense urban metro and suburban networks, providing efficient power delivery for high-frequency services while minimizing overhead infrastructure in tunnels. The maintains the continent's most extensive third rail system, spanning over 2,500 km primarily in the South East, where it powers suburban commuter trains at 750 V . The London Underground exemplifies this dominance, employing a four-rail at a nominal 630 V —comprising a positive outer rail at +420 V and a negative inner rail at -210 V relative to the running rails—for its 402 km network, enabling seamless operation across deep-level and sub-surface lines. Recent expansions, such as the Elizabeth Line's full opening in 2022, use 25 kV AC overhead lines throughout, with connecting suburban segments converted from third rail to support higher speeds up to 140 km/h. France's urban rail systems also heavily feature third rail, with the Paris Métro operating all 16 lines on 750 V DC third rail power, supporting over 1.5 billion annual passengers through its compact 226 km network. The (RER) employs configurations, blending metro-style third rail segments at 750 V DC in central with 25 kV overhead lines on peripheral commuter routes, facilitating integrated regional travel across 587 km. Post-2020 upgrades have focused on energy-efficient enhancements, including advanced power converters to optimize traction and reduce losses in these mixed setups. In the , third rail supports key operations, as seen in Amsterdam's 43 km network powered by 750 V DC bottom-contact third rail for its four lines, and Rotterdam's 100 km system, which uses similar 750 V DC third rail across most routes except short overhead sections on Line E. These implementations align with broader efforts under the Technical Specifications for (TSI), which promote standardized energy subsystems for cross-border compatibility, though third rail remains urban-focused without mandatory voltage unification for non-metro lines. Third rail systems in cities contribute to environmental goals by enabling zero-emission , with electrified networks reducing CO2 output by up to 90% compared to alternatives in high-density areas. Recent 2024-2025 retrofits, such as enhancements on systems like Barcelona's Metro (which recovers 33% of for grid reuse), are being adopted across third rail infrastructures to further cut emissions and integrate with sustainability initiatives.

North America

In , third rail electrification is predominantly utilized in urban systems, providing power to subway and elevated trains in dense metropolitan areas. This method supports high-frequency service in underground and street-level environments where overhead wires are impractical due to clearance issues or aesthetic concerns. Typical voltages range from 600 to 750 V , enabling efficient propulsion for heavy-rail vehicles while minimizing infrastructure complexity in constrained urban corridors. Prominent examples in the United States include the , which operates on a 625 V DC third rail system across its extensive network of over 800 miles of track, powering more than 6,000 subway cars daily. The Chicago 'L' elevated and subway system similarly employs a 600 V DC third rail to energize its fleet, facilitating service on 224 miles of track through the city's core. In the Northeast, the Trans-Hudson (PATH) system connects and , using a 650 V DC third rail for its 14-mile route, serving approximately 300,000 daily riders with automated train control integration. In , the Transit Commission's () subway network relies on a 600 V third rail for its Lines 1 and 2, spanning 68 km and using track to deliver power to modern T-series cars. Vancouver's system incorporates hybrid electrification, with the and Lines utilizing a 750 V third rail alongside linear induction motors for propulsion on 49 miles of guideway, while the employs overhead wires at 750 V . These configurations allow to achieve driverless operation and high capacity in a mix of elevated and underground segments. North American third rail systems face significant challenges from aging , particularly in legacy networks like 's, where century-old components contribute to frequent delays. Ongoing upgrades, such as the Metropolitan Transportation Authority's () signal modernization projects from 2023 to 2025, aim to replace mechanical block signals with (CBTC) on key lines like the and , enhancing capacity and reliability amid a $51.5 billion capital plan. These efforts address voltage fluctuations and power distribution inefficiencies in high-demand corridors. Safety enhancements include the installation of or barriers in select stations post-2020, such as the 's pilot program at three locations (Times Square-42nd Street, Sutphin Boulevard-Archer Avenue-JFK Airport, and Jackson Heights-Roosevelt Avenue) initiated in 2022 and progressing through 2025, which aligns with broader safety standards to prevent track intrusions.

Other Regions

In Asia, the Mass Transit Railway (MTR) in employs a 1,500 V DC overhead catenary system for its urban lines, enabling efficient power delivery in densely populated areas. Similarly, select lines in and metros incorporate 600–750 V DC third rail electrification, though many routes blend it with overhead systems for flexibility in underground environments. Recent developments in have seen increased adoption of third rail systems in new lines opened after 2020, such as extensions in cities like and , where 750 V third rail facilitates compact infrastructure in high-density corridors. These implementations prioritize and reduced visual impact in urban settings. In , the operates primarily on a 750 V third rail system, powering its extensive 226 km network of 12 lines and serving over 1.5 million daily passengers. This setup, chosen for its reliability in the city's seismic conditions and underground routes, exemplifies third rail's role in large-scale urban transit. The Buenos Aires Underground, particularly Line B, uses a non-standard 600 V third rail electrification, which upgraded in 2017 to enhance power supply and tunnel safety. Third rail usage remains limited in Africa and Australia, with Sydney's light rail network featuring an innovative Alstom APS (Alimentation Par le Sol) ground-level third rail system that activates only under passing vehicles for pedestrian safety. Sydney's suburban heavy rail, however, relies on 1,500 V DC overhead lines rather than third rail. In South Africa, potential expansions of electrified commuter networks under PRASA do not currently emphasize third rail, focusing instead on overhead systems for broader freight and passenger integration. Emerging adoptions in highlight growing interest in third rail for metro systems, as seen in the 2024 project replacing steel third rails with lightweight versions between Road and Central stations to improve . This upgrade, part of broader network enhancements, underscores third rail's adaptability in cost-sensitive developing markets.

History

Early Development

The early development of third rail technology stemmed from innovations in electric traction during the late , building on experiments with powered rail systems to replace steam and horse-drawn transport. The first railway to use a central third rail was the Bessbrook and Newry Tramway in Ireland, which opened in 1885 as a 3 ft (914 mm) narrow-gauge hydro-electrically powered line transporting passengers and freight. Granville T. Woods, an African American inventor, contributed significantly by patenting improvements to the third rail system, including a safety-enhanced electric railway in 1901 (US Patent 684,413). Frank J. Sprague played a pivotal role through his 1890s demonstrations of electric streetcar systems, most notably the Richmond Union Passenger Railway in , which began operations in 1888 as the world's first large-scale successful electric street railway, spanning 12 miles over hilly terrain and proving the viability of multiple-unit control for electric vehicles. Although this system primarily utilized overhead trolley wires for power collection, Sprague's advancements in motor design and train control influenced the transition to rail-based electrification methods, including third rail configurations. A key milestone in third rail adoption came with the in , which opened on March 6, 1893, as the world's first mainline electric powered by a central third rail at 525 V DC, positioned between the running rails to supply current to lightweight electric multiple-unit trains. This 6.5-mile dockside line demonstrated the practicality of third rail for urban and industrial transport, using automatic signaling and to enhance efficiency and safety. The system's success highlighted third rail's advantages over overhead wires in enclosed or elevated structures, where wire sagging and maintenance were concerns. In the United States, third rail gained prominence with the Interborough Rapid Transit (IRT) subway in , which commenced service on October 27, 1904, employing a 600 V surface third rail along its 9-mile initial route from City Hall to 145th Street. Powered by contact shoes sliding along the rail, this setup enabled rapid underground transit for the growing metropolis, with trains achieving speeds up to 35 mph and carrying over 300,000 passengers on opening day. The IRT's implementation marked third rail's adaptation to subterranean environments, where overhead lines were impractical due to tunnel height constraints. The technology evolved from earlier conduit systems, which placed a protected conductor in a subsurface slot for streetcars, as pioneered in installations like Washington, D.C.'s Eckington and Railway in 1888 to comply with bans on overhead wires. These conduit setups, adapted from infrastructure, allowed trolleys to draw power via a plow dipped into the slot but suffered from high construction costs, frequent breakdowns from debris and water ingress, and limited speed. By the early 1900s, engineers shifted to exposed surface third rail for dedicated rail lines, offering simpler , better accessibility for , and higher current capacity, though requiring to avoid street-level interference. Prior to 1920, safety challenges dominated third rail deployment, as the exposed high-voltage conductor posed risks to track workers, passengers falling onto rails, and even maintenance crews. These concerns led to innovations like wooden hood covers over the rail to insulate and shield it, as implemented in the IRT system where the third rail was mounted 7 inches above and protected by a 2-inch-thick wood sheath. Physical barriers, such as fenced platforms and rigid insulators, were also introduced to prevent accidental contact, with early regulations mandating insulated shoes and grounding for vehicles; despite these, incidents like shocks during wet weather underscored the need for ongoing refinements in enclosure and detection systems.

Modern Expansion

Following , third rail systems experienced significant expansion in urban metro networks, driven by postwar reconstruction and growing urban populations. In , the opened in stages starting in 1968, representing the first major new line in decades and utilizing the standard 630 V DC fourth-rail configuration to extend connectivity from Walthamstow Central to Victoria. Similarly, the saw extensions to Line 13, with merging of segments from Line 14 in 1976 (planned in the 1960s) to improve north-south links, while maintaining its 750 V DC third rail supply across the growing network. In , the subway's third rail infrastructure (600 V DC) supported planned expansions under the 1968 , which aimed to add over 100 km of new lines, though many projects faced delays; ongoing upgrades included third rail replacements on the IRT lines in the 1970s to enhance reliability. In the , third rail systems have incorporated advancements in and . became prominent with the full driverless operation of in 2011, the oldest line to adopt Grade of Automation 4 using its existing third rail power, improving frequency and safety. technologies, such as DC-DC converters, emerged in the 2010s to capture energy in DC third rail networks, enabling up to 30% efficiency gains by storing or redistributing power back to the grid or other trains. By 2024-2025, efforts integrated renewable sources, exemplified by solar-assisted substations in rail systems; for instance, China's first renewable-integrated railway project on the AC overhead-electrified Baotou-Shenmu line featured a 6 MW at the Liujiagou substation as of October 2025, reducing reliance on fossil fuels, with similar principles applicable to DC third rail urban networks. While third rail use has declined on mainline railways due to speed and safety limitations favoring overhead systems, it persists in urban transit for its compactness in tunnels and . Hybrid approaches promote , as seen with trains equipped for 750 V DC third rail on approaches to the since 1994, allowing seamless cross-border operation. Recent Asian metro builds, such as Metro's upgrades with aluminum third rail segments in 2024, underscore ongoing urban adoption for high-density routes.

Model Railways

Implementation Techniques

In model railways, third rail systems are commonly implemented in O gauge using three-rail , where the center rail serves as the conductive third rail to supply power to locomotives, and are standard in Märklin systems for , , and scales using a center stud contact. Track construction typically involves pre-manufactured sectional pieces made from tubular steel or more realistic tie-and-rail designs, with the center rail embedded or attached between the outer rails using plastic or wooden for stability and aesthetics. For custom or scale-accurate layouts replicating outside third rail, hobbyists often use thin strips or aluminum foil affixed under the with screws or , ensuring electrical continuity while mimicking prototype elevation and . These conductive elements are powered by dedicated transformers delivering 12-18 volts or , depending on the system, to provide reliable low-voltage operation suitable for indoor layouts. Locomotives in third rail model setups employ wiper pickups mounted on sliding shoes that maintain with the center , replicating the sliding shoes of full-scale third . These pickups, often made from or spring-loaded metal, are positioned on the to rub against the surface, ensuring uninterrupted power delivery even during curves or elevation changes; in more advanced models, multiple shoes per enhance reliability by distributing points. Layout designs incorporating third rail emphasize insulated sections to create electrical gaps, preventing short circuits at block boundaries or turnouts, achieved by inserting non-conductive insulators or gaps in the center rail while maintaining outer rail continuity. Compatibility with (DCC) is facilitated through specialized decoders installed in locomotives, such as those from QSI or ESU, which convert the AC track power to DC for precise speed and sound control across multiple units on the same layout. Historically, early 20th-century third rail models relied on construction, featuring stamped tracks with prominent tubular three-rail designs for durability and simple wiring, as seen in Lionel and Ives products from the to . In contrast, modern implementations adhere to National Model Railroad Association (NMRA) standards for accuracy, using finer-profile rails and realistic to achieve prototypical appearance while supporting advanced electronics like .

Challenges and Adaptations

Modeling third rail in small scales such as and presents significant challenges due to the need for fine, realistic rail sections that can compromise electrical . The thin code 60 rail commonly used for the third rail in these scales, like Peco's IL-1, often requires additional feeders or joiners to mitigate voltage drops and ensure reliable power delivery to locomotives. To address this, modelers employ flexible wiring solutions, such as stranded wire connections between rail sections, to maintain consistent without rigid joints that could cause breaks on curves. Derailment risks arise from uneven rail height or poor , particularly on curves or at transitions, where the third rail must be precisely positioned no more than 1mm above the running rails to avoid interference with flanges. Solutions include using IL-120 conductor rail chairs to secure the rail at consistent heights and drilling for secure mounting, allowing for smoother operation. In larger scales like O gauge, these issues are less pronounced due to the bigger components, enabling easier hand-laid track with extended ties for support, as described in techniques inspired by Frank Ellison's methods. For enhanced realism, adaptations such as lighted gaps simulate the visual effect of power collection, using LED modules like the Train Tech TTAL23 to flash at pickup points on third rail-equipped models. Sound effects for arcing are achieved through digital decoders, such as ESU LokSound V5, which include synchronized buzz triggered by function keys during operation. Post-2020 innovations include automatic lighting effects integrated with systems for more dynamic power simulation, particularly in urban layouts. In large layouts, systems combine third rail with overhead lines for prototypical transitions, using insulated gaps and flexible wiring to switch power sources seamlessly. practices often involve from brands like for British-style outside third rail in HO/OO and Märklin's center-rail adaptations in for continental European models, with detailed tutorials promoting precise modifications.

References

  1. [1]
    Third rail - Network Rail
    When we talk about the third rail, we mean the live rail which provides electric power to a train through a conductor placed alongside the rails. This network ...
  2. [2]
    Overhead lines vs third rail: how does rail electrification work?
    Sep 13, 2023 · The third rail electrification system, also known as the contact rail system, provides power to trains through a conductor rail placed alongside ...
  3. [3]
    The History of 'Third Rail' - Merriam-Webster
    Oct 10, 2017 · The term 'third rail' originated from the literal third rail in subways, which powers trains, and is now used metaphorically for controversial ...
  4. [4]
    Electric Traction Power | PRC Rail Consulting Ltd
    The third rail system uses a "shoe" to collect the current on the train, perhaps because it was first called a "slipper" by the pioneers of the industry (it ...
  5. [5]
    [PDF] Safety of High Speed Guided Ground Transportation Systems
    Operating on a system of any established third rail or catenary voltage, larger trains requiring greater motive power will draw more current and produce larger.
  6. [6]
    Third Rail and 3rd Rail System Details - Rail Fasteners
    The steel-aluminum composite third rail is a contact rail formed by mechanically combining a stainless steel belt with an aluminum alloy profile. It adopts ...Missing: copper | Show results with:copper
  7. [7]
    Aluminum-stainless steel conductor (third) rail and method
    Third rail conductivity will be a function of SS & Al cross sections, the nature of the bond at the SS/A1 interface, and the Al alloy composition used for the ...
  8. [8]
    Aluminum-Stainless Steel 3rd Rail Technology PDF - Scribd
    to transit vehicles. Since the early years of railway electrification, 3rd rail conductors have evolved from steel to aluminum/steel composite to aluminum/ ...
  9. [9]
    Third Rail Insulators & Conductor-Rail Supports | gipro.com
    Third rail insulators are solid epoxy, UV and weather resistant, made of cycloaliphatic epoxy resin, and are used to support conductor rails in train systems.Missing: bonds | Show results with:bonds
  10. [10]
    Third Rail Accessories - L.B. Foster
    Third rail accessories include splice bars, end/side approaches, expansion joints, coverboard, brackets, insulators, anchor rods, and more.Missing: bonds | Show results with:bonds
  11. [11]
    Third Rail Connection Accessories - MAC Products
    MAC Products offers third rail accessories like connectors, covers, signal bonds, junction boxes, power products, insulators, compression lugs, support ...
  12. [12]
    [PDF] ccd shoes - CURRENT COLLECTION BY THIRD RAIL - MERSEN
    A CCD shoe consists of a carbon part mounted on a supporting carrier. The carrier's role is to protect the carbon collector from impacts, to resist deflection ...Missing: patterns | Show results with:patterns<|control11|><|separator|>
  13. [13]
    3rd Rail Current Collector Market | Global Market Analysis Report
    Aug 12, 2025 · Abrasion-resistant materials are being specified in collector shoes to address accelerated wear caused by high-frequency service patterns.
  14. [14]
    [PDF] How Track Circuits detect and protect trains - railwaysignalling.eu
    The purpose of the impedance bonds is to provide continuity between the track circuits for the DC propulsion power and to distribute the propulsion current ...<|control11|><|separator|>
  15. [15]
    Chapter 2 | Third Rail Insulator Failures: Current State of the Practice
    Read chapter Chapter 2 - Literature Review: Third rail systems provide traction power to electrified rail systems in many parts of the world, including th.Missing: benefits | Show results with:benefits
  16. [16]
    Traction choices: overhead ac vs third rail dc
    As a solid composite rail running along the track, a third rail is more rugged than an overhead contact wire and has a longer life expectancy. The system ...
  17. [17]
    Winter weather - snow and ice - Network Rail
    Ice can coat the electrified third rail and overhead power cables, preventing trains from drawing the power they need to run and leaving them stranded.Missing: limitations | Show results with:limitations
  18. [18]
    How we prepare for winter - CTA
    All railcars have "sleet scrapers" that are lowered to keep the third rail clear of snow, sleet and ice. ... Track switch heaters tested and serviced to melt snow ...Missing: covers | Show results with:covers
  19. [19]
    CTA prepares for winter weather to ensure safe and efficient service
    Nov 20, 2024 · Some railcars are also outfitted with deicer fluid distribution systems that prevent ice from accumulating on the third rail, a crucial measure ...Missing: L covers
  20. [20]
    Development of Strategies to Prevent Third Rail Insulator Failures in ...
    Mar 24, 2021 · This study examines various aspects of third rail systems, identifies causes of insulator failures, and develops and categorizes preventive strategies.
  21. [21]
    Chapter 2 | Third Rail Insulator Failures: Current State of the Practice
    Read chapter Chapter 2 - Literature Review: Third rail systems provide traction power to electrified rail systems in many parts of the world, including th.
  22. [22]
    [PDF] Onboard energy storage for discontinuous, safer third rail DC ...
    It is found that using an energy storage system can bridge 300 m gaps in the conductor rail within stations effectively with minimal impact on the timetabled ...<|control11|><|separator|>
  23. [23]
    Man survives 750-volt shock after falling on to live rail - The Guardian
    Nov 23, 2016 · Chris Dos Santos suffered cardiac arrests and nearly had to have leg amputated after electricity 'stuck' him to railway track.
  24. [24]
    Electrical injury from subway third rails - PubMed
    Results: A total of 16 cases was identified. Among seven subway workers, the mechanism of rail contact was unintentional by a tool, a hand or by falling; no ...Missing: historical | Show results with:historical
  25. [25]
    Majority unaware of dangers of third rail – survey | The Independent
    Apr 2, 2025 · The survey also suggested 38% of people believe electrocution from rail tracks will not cause serious injury. ... Network Rail recorded a 20% ...
  26. [26]
    Bereaved mother whose daughter was electrocuted by a railway ...
    Apr 6, 2025 · Jade Kenyon died after being snared by the “third line” electric current emitted from a live rail near North Halling in Kent.
  27. [27]
    49 CFR Part 214 -- Railroad Workplace Safety - eCFR
    49 CFR Part 214 aims to prevent accidents and casualties for railroad employees in inspection, maintenance, and construction, and sets minimum safety standards.
  28. [28]
    NFPA 130 Standard Development
    This standard specifies fire protection and life safety requirements for underground, surface, and elevated fixed guideway transit and passenger rail systems.
  29. [29]
    Platform gates and doors | Federal Railroad Administration
    Platform edge doors are full height but do not reach the ceiling. These two types of doors completely restrict physical access to the track area. Platform gates ...
  30. [30]
    Safer Faster Isolation - Targeted Assurance Review - March 2021
    Mar 11, 2021 · The safer faster isolation (SFI) programme was developed to minimise the risk of serious injury or death when working on or near electrical equipment.Missing: Smarter | Show results with:Smarter
  31. [31]
    The third protocol - Modern Railways
    Jun 25, 2020 · The Merseyrail network is soon to add route extensions using batteries, while in the long-term there is little doubt that extending the ...
  32. [32]
    Real time insight to shoe vs. third rail intimate contact
    Oct 30, 2025 · Two rugged coil springs fitted on the current collector ensure constant contact of the shoe against the power rail. This physical contact paired ...Missing: mechanism | Show results with:mechanism
  33. [33]
    Third Rail Current Collector - Hall Industries
    Underrunning or overrunning contact shoe · Coil spring loaded paddle designed to meet contact force specifications · Cable shunted paddle to eliminate current ...Missing: mechanism | Show results with:mechanism
  34. [34]
    Third-Rail Current Collectors - Schunk Group
    Our 3rd rail current collectors for metros, subways or monorail vehicles ensure safe power transmission into the vehicle through uninterrupted contacting.Missing: mechanism | Show results with:mechanism
  35. [35]
    [PDF] Traction Power Electrification System Investigation (WMATA)
    Dec 9, 2016 · This is a final report on the Traction Power Electrification System Investigation for WMATA, including an executive summary and introduction.<|control11|><|separator|>
  36. [36]
    Rigid Catenary (or Overhead Contact System) | - railsystem.net
    The rigid catenary is an Overhead Contact System (OCS) using an aluminum alloy profile to hold the contact wire, replacing contact wire, third rail or T-rail.
  37. [37]
    [PDF] Current Collection Technical Guide MERSEN
    Steel, cast-iron, copper or bronze shoes on third rail collection systems mechanically damage the rail due to their relatively high mass. Carbon has many ...
  38. [38]
    Overview of stray current control in DC railway systems
    In DC rail transit systems, the running rails are usually used as the return conductor for traction current. This arrangement mainly focuses on economic ...
  39. [39]
    [PDF] Track Design Handbook for Light Rail Transit (Part D)
    The direct current is picked up by a vehicle pantograph to power the motor and then returns to the substation via the running rails, which become the negative.
  40. [40]
    Track circuits on the third rail network
    Jul 18, 2005 · The DC can flow from both rails, via the impedance bond (sunk into the four foot) into the sleeper mounted metal busbar plate. It bypasses the ...Missing: signaling | Show results with:signaling
  41. [41]
    Measures and Prescriptions to Reduce Stray Current in the Design ...
    Rails should be continuously welded, and frequent cross-bonding between rails should be provided to ensure multiple parallel paths for the return current; the ...<|control11|><|separator|>
  42. [42]
    Development and performance analysis of a novel impedance bond ...
    Jun 1, 2013 · The impedance bond is shown to eliminate interference while meeting the requirements of signal transmission on rail tracks. In this study, both ...
  43. [43]
    [PDF] INTERFERENCE OF ELECTRIFICATION WITH SIGNALING AND ...
    As Figure 10 shows, an impedance bond is a center- tapped coil wound on an iron core. The ends of the coil are connected to the rails near the insulated joints ...
  44. [44]
    [PDF] Stray Current Corrosion in Electrified Rail Systems -- Final Report
    By increasing this resistance, the stray-current path is less favorable than the running-rail return path, resulting in less stray current.
  45. [45]
    Effects of earthing systems on stray current for corrosion and safety ...
    Stray current is the main cause of corrosion in metallic parts located in the railway proximity. This study reviews various earthing schemes including thyristor ...
  46. [46]
    [PDF] TRACTION SYSTEMS, GENERAL POWER SUPPLY ...
    3 May 2012 · energy saving purpose. From the above, it can be inferred that the line losses in 750V dc third rail system is around 11% more than ac system.
  47. [47]
    [PDF] IRTB August-2013.pmd - RDSO - Indian Railways
    A high resistance of the running- rail negative return increases the voltage drop along the rails and, therefore, makes the rail-to-earth return circuit a more ...<|control11|><|separator|>
  48. [48]
    Neutral sections | RailUK Forums
    Jun 12, 2015 · For a train to stop with it's pan under a neutral zone is very rare as they are only possible 20' in length. ... third-rail train stopping with ...Questions about Neutral Sections | RailUK ForumsNeutral Section next to a Station? - RailUK ForumsMore results from www.railforums.co.uk
  49. [49]
    Third Rail AND Overhead - Transit - Trains.com Forums
    Aug 15, 2009 · NJ Transit ALP44 (similar to Amtrak AEM-7) and ALP46 electric locomotives switch over automatically between the 2 voltages. Both lines use ...Missing: devices | Show results with:devices<|separator|>
  50. [50]
    Automatic Switching of Electric Locomotive Power in Railway ... - MDPI
    This paper proposes using computer vision to detect visual markers, which trigger vacuum circuit breakers to switch locomotive power in neutral sections.
  51. [51]
    Southern Region DC 3rd length - UK Prototype Questions - RMweb
    Nov 18, 2015 · There are maximum specified lengths of conductor rail (dependant on track radius) up to about 1800ft long before an expansion gap is required ( ...
  52. [52]
    The Railway Power Stations of New York City
    The Third Avenue Railroad was a surface line which originally used horses for motive power. Later, it was equipped with mechanical cables running in underground ...
  53. [53]
    The New York Subway: Chapter 05, System of Electrical Supply
    The system of electrical supply chosen for the subway comprises alternating current generation and distribution, and direct current operation of car motors.
  54. [54]
    Overhead vs third rail: how does rail electrification work? - Future Rail
    Jul 10, 2023 · One of the significant advantages of third rail electrification is its cost-effectiveness. Compared to overhead lines, the installation and ...Missing: standards | Show results with:standards
  55. [55]
    [PDF] HS1 Network Statement 2026 (November 2024 update)
    Jul 11, 2025 · The power supply at the North Kent line connection, and the Ashford domestic connecting lines, is through conventional NRIL 750V DC third rail ...
  56. [56]
    Light Rail System, operated by Thameslink Rail - Railway Technology
    Jul 6, 2000 · They operate on 25kV AC overhead power north of Farringdon, from where they switch to 750V DC third rail operation.
  57. [57]
    [PDF] LNW Route Specification 2017 - Network Rail
    North West Electrification programme on the Blackpool North line, with ... SRS E.02 North London Line - Willesden Junction to Gospel Oak. LUL Network ...
  58. [58]
    Providing the energy for your transport | Network modernisation
    Sep 24, 2025 · The high-voltage electricity bought from various suppliers is delivered at 63 kV or 225 kV to 7 high-voltage substations located all over Paris.
  59. [59]
    Amsterdam Metro / Light Rail Network by GVB - Railway Technology
    Feb 16, 2017 · These operate at a 600V power supply through overhead lines, while the light rail system is supplied through a 750V DC third rail. The new ...
  60. [60]
    Has third rail had its day? - Rail Engineer
    Apr 10, 2013 · With the emphasis on growing electrification and the possible spread of 25kV into traditional third rail electrified areas, this was felt to be ...
  61. [61]
    https://www.railway-technology.com/projects/amsterdam-metro-light-rail/
  62. [62]
    https://www.railengineer.co.uk/has-third-rail-had-its-day/
  63. [63]
    North Eastern Railway pioneer electric locomotives - Key Model World
    Jan 16, 2023 · ... British Thomson-Houston. Both were of the centre cab design, with a sloping bonnet at each end and equipped with a single pantograph ...
  64. [64]
    London Underground/Overground traction voltage - RMweb
    Aug 17, 2013 · London Underground's 4 rail system supplies current with the outer (3rd) rail at + 420v and the inner (4th) rail at - 210v with respect to ground (running ...Traction Current - London UndergroundLondon Underground/Overground traction voltage - Page 2More results from www.rmweb.co.uk
  65. [65]
    Controlling the Elizabeth line - Rail Engineer
    Jul 10, 2023 · Electrification and power​​ The Elizabeth line is 25kV overhead line throughout the route using a 50kV auto-transformer feeding configuration ...
  66. [66]
    Customised battery locos ordered to haul Paris metro maintenance ...
    Oct 21, 2024 · The locos will use the metro's 750 V DC third rail power supply when available, and also to recharge the batteries, which will provide power ...Missing: hybrid | Show results with:hybrid
  67. [67]
    How to save energy and costs while braking | Alstom
    Dec 8, 2021 · Hesop is a reversible substation power converter which is installed between the public energy network and the train overhead line or 3 rd rail.Missing: retrofits | Show results with:retrofits
  68. [68]
    UrbanRail.Net > Europe > Netherlands > ROTTERDAM Metro
    The route runs underground and parallel to the river towards the city centre, where interchange to the Erasmuslijn is provided at Beurs (formerly Churchillplein) ...
  69. [69]
    https://www.alstom.com/press-releases-news/2021/12/how-save-energy-and-costs-while-braking
  70. [70]
    Rail - IEA
    Jul 11, 2023 · The low energy and CO2 intensities of rail transport make promoting rail a promising strategy to diversify energy sources and reduce emissions.
  71. [71]
    Regenerative Braking Produces Power, Revenue for Barcelona ...
    Oct 7, 2024 · 33% of the energy used by the trains comes from regenerative braking, enough to power 25 subway stations, said Jordi Picas, who leads the project.
  72. [72]
    Facts about New York City subways and buses - MTA
    Substations receive as much as 27,000 volts from power plants and convert it for use in the subway. The third (contact) rail uses 625 volts to operate trains.Missing: voltage | Show results with:voltage
  73. [73]
    Operations - Traction Power - Chicago ''L''.org
    Third rail systems are a means of providing electric traction power to trains, and use an additional rail (called a "conductor rail", "trolley rail", or ...
  74. [74]
    PATH Port Authority Trans-Hudson - nycsubway.org
    Power Source, 650V DC third rail. Work Fleet, (as of 1/1/1997) 12 flat cars, 31 work cars, 3 ballast cars, 2 snow plows, crane car, snow broom car, tamper ...Missing: voltage | Show results with:voltage
  75. [75]
    Toronto Transit Subway System - Railway Technology
    Apr 25, 2007 · The Toronto Subway is built to a unique gauge of 1,495mm, rather than the 1,435mm standard and is powered at 600V DC, with trains collecting ...
  76. [76]
    Vancouver SkyTrain - Railway Technology
    May 18, 2000 · Power supply by third rail and the reaction plate for the train's linear induction motors are incorporated in a permanent way. A notable ...
  77. [77]
    SkyTrain High Technology Rapid Transit in Vancouver - jstor
    Power Supply: 650 volts DC, third rail collection. Power Return: Via fourth rail, +.325 volts. Power conversion is on board using power transistors to vary ...
  78. [78]
    CBTC: Upgrading signal technology - MTA
    We've made improvements to modernize our signals over the decades, but the basic technology is unchanged. Newer, modern signals can provide our riders with ...
  79. [79]
    MTA Releases Proposed 2025-2029 Capital Plan
    Sep 18, 2024 · Signal modernization. Replacement of decades-old mechanical signals with Communication Based Train Control (CBTC) technology across more than 75 ...
  80. [80]
    MTA Opens Door to Platform Barriers in Three Subway Stations
    Jul 15, 2022 · The MTA has put up a want ad for companies seeking to install platform barriers at three stations in the subway system.
  81. [81]
    1500 V DC railway electrification in Hong Kong - Checkerboard Hill
    Jun 23, 2021 · Hong Kong MTR uses electric trains, powered by two different technologies – 1500 V DC on the 'urban' rail lines, and 25 kV AC for the former KCR network.
  82. [82]
    Alstom to renew Buenos Aires Line B power supply
    Line B is electrified at 600V dc third rail and the 15-month project involves installation of new medium-voltage ring cables, third rail power supply and tunnel ...
  83. [83]
    Catenary-free tram running tested in Sydney - Railway Gazette
    Jul 30, 2019 · APS uses an embedded third rail to supply power to trams, with the conductive segments live only while a tram is passing over them. Advert.
  84. [84]
    South Africa - Rail Infrastructure - International Trade Administration
    Jan 30, 2024 · The South African Government's plans to spend R900 billion by 2027 on rail infrastructure, have been beset by regulatory and organizational ...
  85. [85]
    Kolkata Metro replaces steel third rail with aluminium between ...
    Nov 30, 2024 · Kolkata Metro achieves a breakthrough by replacing its steel third rail with an aluminium third rail between Mahatma Gandhi Road and Central ...
  86. [86]
    Frank Sprague - Lemelson-MIT
    In 1887, Sprague began the installation of a 12-mile electric rail system in Richmond, VA, for the Richmond Union Passenger Railway. This was to be the ...Missing: third | Show results with:third
  87. [87]
    Frank J. Sprague - Linda Hall Library
    Jul 25, 2025 · In 1884, Sprague invented a new electric motor that was brushless (and so did not spark) and provided constant speed, no matter the load. It was ...
  88. [88]
    3rd and 4th rail dimensions and settings - CLAG
    A purpose of this page is to aid 4mm scale modelling, and dimensions on the drawings are given accordingly, except where otherwise specified.
  89. [89]
    Interborough rapid transit: the New York subway, its construction ...
    A published book, Interborough rapid transit; the New York subway, its construction and equipment (1904) presents the construction of the ...
  90. [90]
    A Streetcar City | National Museum of American History
    Electric streetcar, 1898​​ Washington banned overhead wires, so streetcars used an underground electrical conduit within the city and an aboveground wire outside ...
  91. [91]
    Transit Innovator: Granville T. Woods - New York Transit Museum
    This invention used the idea of 'induction': a large battery-powered magnet was put underneath the train, attached to a telegraph or telephone in the train ...
  92. [92]
    The Victoria line | London Transport Museum
    It opened in 1968 between Walthamstow Central and Highbury & Islington, and on to Warren Street a few months later. The line was completed to Victoria in 1969 ...Missing: third rail
  93. [93]
    Metro line 14: a line and its history | Culture - RATP
    Sep 3, 2025 · It has been 25 years since line 14, the first fully automated line on the Paris network, was commissioned and began operating. Unlock the full history with us!
  94. [94]
    The New York Transit Authority in the 1970s - nycsubway.org
    Replacement of third rail on the IRT between 168th Street and Dyckman Street in Manhattan. Transit improvements planned for 1979 included. Welded rail along ...The 1968 MTA "Program for... · Construction Begins · The "Program For Action" 5...
  95. [95]
    Driverless metro lines break new worldwide record
    Jun 25, 2018 · Automated metros have now reached a combined 1000 km around the world. But which networks stand out in terms of performance, longevity and ...
  96. [96]
    [PDF] Recuperation of Regenerative Braking Energy in Electric Rail ... - arXiv
    There are three common voltage levels for the third rail in. DC transit systems: 600V, 750V and 1500V [6]. The operating third rail voltage is maintained ...
  97. [97]
    China launches its first railway project integrating renewable energy
    Oct 9, 2025 · The line's Liujiagou substation, which has a 6-megawatt photovoltaic power generation system, is a key source of the project's solar energy, ...<|control11|><|separator|>
  98. [98]
    High Speed 1 (HS1), United Kingdom - Railway Technology
    Apr 11, 2022 · Each train operates using the three different electrical systems used on the railways of Britain, France, and Belgium, which include 750VDC ...
  99. [99]
    new aluminium third rail installed at mahatma gandhi road metro ...
    Dec 2, 2024 · Metro Railway has replaced successfully steel third rail of its two yard lines at Girish Park and Maidan by Aluminium third rail brought from Germany.
  100. [100]
    The basics of 3-rail track - Trains Magazine
    Aug 12, 2024 · Choosing the right O-gauge, 3-rail track can put you on the right track when building a layout in scale, semi scale, or even a mixture of both.
  101. [101]
    https://www.trains.com/ctt/how-to/expert-tips/the-basics-of-3-rail-track/
  102. [102]
    3rd Rail Shoes that Pickup Electricity - Trains.com Forums
    May 25, 2008 · It's just a matter of deciding where to install one and how to reach in to activate it. Chuck (modeling Central Japan in September, 1964).3rd rail in HO and other matters of note and observationsOutside third rail - General Discussion (Model Railroader)More results from forum.trains.comMissing: railroad | Show results with:railroad
  103. [103]
    3 Rail trains and DCC? | O Gauge Railroading On Line Forum
    Oct 4, 2024 · I've been thinking about maby trying to put a DCC system into my 3 rail trains. I have a TMCC system with about six of their accessory ...
  104. [104]
    DCC In O Gauge is Here!! Blunami DCC!! - YouTube
    Oct 5, 2023 · For decades the reigning champions of the 3 rail O scale market have been Lionel Legacy and MTH DCS; however, a new challenger has entered ...<|control11|><|separator|>
  105. [105]
    Scale Or Tinplate - eTrain Article - Train Collectors Association
    Tinplate is steel that has been coated with tin to protect against rusting. Most prewar toy trains were built from stamped sheet metal, so the term tinplate ...
  106. [106]
    https://www.tcatrains.org/etrain/scale-or-tinplate/
  107. [107]
    Code 60 Flat Bottom Rail Nickel Silver 609mm (x6) - Peco IL-1 - eBay
    In stock Rating 4.8 (5) Lenght : 609mm. (24in) x 6 For Z Scale and also used as OO Scale Conductor Rail. To be used with il-120 to replicate the third rail on Southern Railway ...
  108. [108]
    Laying Peco 3rd Rail - Southern Electric Group
    This is my experience of laying 24 real feet of third rail on my 00 layout using Peco IL-120 conductor rail chairs, IL-1X code 60 rail section, and joiners SL- ...
  109. [109]
    Outside 3rd Rail - J&C Studios O Gauge Archive
    The ties and tie spacing were chose based on Frank Ellison's technique as described in his book. Ties are 1/8" high x 1/4" wide by 2-1/4" long with 2-3/4" ties ...
  110. [110]
    http://www.jcstudiosinc.com/Outside-Third-Rail
  111. [111]
    3rd Rail Division of Sunset Models
    3rd Rail, while still part of Sunset Models strives to bring this attention to detail and scale to the collector and operator of 3 rail O scale. That is why ...