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Harold Interlocking

Harold Interlocking is a major railroad junction in , , , serving as the primary convergence point for Amtrak's and the (LIRR) Main Line and . It is recognized as the busiest passenger rail interlocking in , managing the routing of hundreds of trains daily through the to and from in . Constructed in 1908 by the as part of the project—which included the development of , the , the , and —Harold Interlocking was designed to handle the influx of rail traffic entering from the east. The facility derives its name from the nearby Harold Avenue, now known as 39th Avenue. Initially operated via manual signal towers, control shifted to a computerized system at in the mid-1990s, enhancing operational efficiency amid growing commuter and intercity demands. In its modern configuration, Harold Interlocking features an extensive array of track switches and signals that prevent conflicting train movements, accommodating approximately 735 LIRR trains and about 50 trains each weekday (as of 2025). Its strategic location near makes it a critical chokepoint for regional rail service, where delays originating here can cascade across the , impacting millions of passengers. Recent infrastructure upgrades, completed as part of the MTA's project in 2021, have significantly modernized the interlocking to support expanded LIRR service to , with full service beginning on January 25, 2023. These enhancements include the installation of 97 new track switches, 295 poles for Amtrak's overhead wires, five new steel railroad bridges, and over 8,400 feet of retaining walls, all aimed at increasing capacity and reliability. The Westbound Bypass for trains, completed in 2025, addresses congestion and facilitates smoother integration between LIRR and Amtrak operations.

Overview

Description

Harold Interlocking is a large railroad and junction situated in , , that serves as the primary connection point between Amtrak's and the Long Island Rail Road's Main Line and . As the busiest rail junction in the United States, it handles 783 trains on weekdays, facilitating the convergence and divergence of commuter and intercity services. The interlocking comprises a complex series of interconnected switches, signals, and tracks engineered to enable precise and safe train routing, minimizing conflicts and preventing collisions at this high-volume crossover. These components manage the intricate flow of trains emerging from the and branching toward or continuing along the . It employs a system to accommodate the differing requirements of its operators: electrification at 750 V DC for LIRR trains and overhead at 25 kV 60 Hz AC for services. As of 2025, Harold Interlocking is fully operational following the completion of the project in 2023, with the eastbound bypass track now active to enhance throughput by reducing conflicts with LIRR movements.

Significance

Harold Interlocking is recognized as the busiest rail junction in the United States, managing a complex convergence of tracks that handle approximately 783 trains on weekdays, including more than 40 per hour during peak periods. This high volume underscores its pivotal role in coordinating movements across multiple rail lines, where even minor disruptions can cascade through the system. The interlocking plays a crucial role in facilitating both intercity services operated by on the and commuter services of the (LIRR), enabling seamless integration that supports regional mobility. It accommodates over 300,000 daily passengers, primarily LIRR commuters traveling to and from , alongside 's high-speed and regional trains connecting the Northeast megaregions. This connectivity enhances access to major economic hubs, fostering efficient transport links between , , and points north and south along the Corridor. Economically, Harold Interlocking is vital for the Northeast Corridor's overall efficiency, where congestion at this junction contributes to significant delays that cost millions annually in lost productivity and operational inefficiencies. A single day of major disruptions on the Corridor could result in up to $100 million in economic losses, highlighting the interlocking's strategic importance in sustaining commerce and workforce mobility across eight states. Its capacity constraints amplify the need for reliable operations to minimize these impacts. The interlocking's complexity has also been linked to notable safety incidents, such as the August 1, 2018, of an LIRR train, where the first axle jumped the tracks, suspending service and underscoring vulnerabilities in high-traffic environments. This event, which caused no injuries but led to widespread delays, emphasized the ongoing requirement for infrastructure upgrades to mitigate risks at this critical node.

Location and Infrastructure

Geographical Position

Harold Interlocking is located at the eastern terminus of the , immediately adjacent to in [Long Island City](/page/Long Island City), , . This positioning places it within a critical nexus of rail infrastructure, serving as a primary junction for intercity and services entering from the east. The site is bounded to the south by Skillman Avenue and to the north by the , integrating it into the dense urban fabric of western . The interlocking maintains direct connections to the Hell Gate Line extending northward toward and various (LIRR) branches radiating eastward along the Main Line, facilitating seamless transitions for both and LIRR operations. It lies in close proximity to the Honeywell Street Bridge, which spans the yard and supports local vehicular traffic over the tracks. Approximately situated at 40°44′53″N 73°55′42″W, Harold Interlocking occupies a strategic point along the , approximately 3.5 miles east of . Encompassing both elevated and at-grade tracks, the facility operates within a heavily industrialized and transportation-oriented zone interspersed with residential neighborhoods in Sunnyside and . This urban setting, characterized by proximity to major roadways like Northern Boulevard and , necessitates ongoing environmental management, particularly for and ground-borne from rail activities. Project-specific trackwork and infrastructure modifications, such as those associated with the initiative, incorporate mitigation measures compliant with criteria to minimize impacts on surrounding communities, including resilient rail fastenings and vibration-isolating designs evaluated in environmental impact studies completed in 2001.

Track Configuration

Harold Interlocking encompasses 14 tracks, integrating the four-track mainline with the Long Island Rail Road's (LIRR) four-track Main Line and two-track to manage high-volume intercity and commuter traffic. This layout supports joint operations, with holding primary use of NEC Tracks 1 and 2 and secondary use of LIRR Tracks 3 and 4, while the LIRR maintains primary access to its lines. The configuration includes numerous crossovers for flexible routing between parallel tracks, enabling efficient merging and diverging of trains from the NEC and LIRR systems. Key features of the interlocking include diamond crossings at the LIRR-NEC , where tracks intersect to allow passage of both and LIRR services, alongside grade-separated sections implemented post-improvements to minimize conflicts. These elements facilitate the complex weaving of routes, with the LIRR tracks positioned at a lower level than the NEC in certain areas for enhanced safety and capacity. Additionally, power supply transitions occur within the , shifting from third-rail for LIRR operations to overhead for trains on the NEC. Recent enhancements include two new bypass tunnels—one for eastbound (completed May 2025) and one for westbound (under as of November 2025)—constructed as part of projects from 2023 onward to separate traffic from LIRR flows, reducing congestion at the junction. These grade-separated es provide conflict-free paths for trains, improving overall throughput. The employs power-operated switches equipped with electro-pneumatic point machines, which use electric controls to direct pneumatic pressure for precise and rapid track changes. This hardware ensures reliable routing amid the high density of movements through the facility.

Operations

Daily Traffic

On a typical weekday, Harold Interlocking processes approximately 783 trains. This volume underscores the junction's role as a critical convergence point for the (NEC) and LIRR Main Line, where trains from multiple operators merge before entering . Peak traffic intensifies during morning and evening rush hours, exceeding 40 trains per hour. The diverse traffic composition features high-speed services, LIRR local and express commuter trains, and infrequent runs via the Line, as the project remains delayed until at least 2030. Capacity limitations previously led to significant operational conflicts and delays due to route interferences at the multi-line junction. Following completion of the East Side Access project in 2023, including enhanced signaling and track realignments, operations have become more efficient, supporting expanded LIRR service to Grand Central Madison.

Control and Signaling

The control of Harold Interlocking is managed remotely from the Penn Station Control Center in New York City, a practice established since the 1990s to centralize operations for Amtrak and Long Island Rail Road (LIRR) trains. This setup employs centralized traffic control (CTC), which allows dispatchers to monitor and direct train movements across the complex junction in real time, optimizing routing and reducing delays through integrated track and signal oversight. The signaling system at Harold Interlocking originally relied on a relay-based but was upgraded in 2018 to a microprocessor-based design, enhancing reliability and response times with built-in redundancies for vital functions. This modern system uses dual-channel microprocessors to execute safety-critical logic, ensuring precise control over route selections and preventing operational errors. Key protocols include combined with cab signals, where wayside equipment transmits speed and occupancy information directly to locomotives, allowing engineers to maintain safe intervals without fixed restrictions. The logic inherently safeguards against conflicting routes by verifying switch positions and signal aspects before authorizing movements. Safety is further bolstered by integrated features such as derailers, which physically block unauthorized track access, and hot axle detectors positioned along approaches to identify overheating bearings or mechanical faults in passing trains. Since 2020, (PTC) has been fully implemented across the interlocking, overlaying the existing signals with automated enforcement to prevent overspeed, misaligned switches, and incursions into work zones, significantly reducing collision risks. These elements collectively enable the safe handling of diverse traffic, including high-speed services and LIRR commuter operations.

History

Original Construction

The (PRR) initiated construction of Harold Interlocking in 1908 as a critical component of the project, a massive engineering endeavor that included the development of , the under the , and the beneath the East River. This project, authorized by the New York Improvement Company—a PRR subsidiary—aimed to establish a direct, all-rail connection into for both passenger and freight services, bypassing the inefficient ferry operations across the rivers that had previously dominated rail access to . The interlocking's placement in , facilitated the seamless integration of the new tunnel infrastructure with the existing (LIRR) network, which the PRR had acquired in 1900 to support yard and routing operations. The primary purpose of Harold Interlocking was to enable through service from the newly constructed Penn Station via the , allowing trains to avoid street-level crossings and congestion in while routing efficiently toward destinations on and beyond. By controlling the convergence of the four single-track —two for inbound and two for outbound traffic—with the LIRR's main lines and , the interlocking addressed the complex routing needs of high-volume passenger traffic entering from the west. This setup eliminated the need for trains to terminate in and ferry across the , revolutionizing connectivity and supporting the PRR's goal of a unified network. The facility's strategic location near provided essential storage and turnaround capacity for up to 1,387 cars across 53 miles of track, underscoring its role in managing the project's operational scale. Harold Interlocking's original incorporated an electro-mechanical interlocking housed in the dedicated Harold Tower, a structure typical of PRR's early 20th-century signaling architecture, which utilized levers to operate track switches and signals for safe train movements. Integrated directly with the four-track tunnel approach emerging from the , the ensured precise control over diverging routes, including connections to the LIRR Main Line and , preventing conflicts in one of the densest rail junctions of its era. This electro-mechanical setup, powered by standard PRR signaling principles, represented advanced technology for the time, allowing operators to manage multiple crossovers and protective signals with mechanical precision. The tower's name derived from nearby Harold Avenue (later renamed 39th Avenue), reflecting local geography. The interlocking became fully operational on September 8, 1910, coinciding with the opening of and the completion of the tunnel extensions, marking the culmination of seven years of construction that had begun in 1903. This activation enabled the first through trains from Penn Station to traverse the and proceed eastward without interruption, instantly transforming rail travel in the . The PRR's investment in Harold Interlocking, estimated within the broader $100 million project cost, highlighted its foundational importance to the regional rail system's efficiency and safety.

Early Renovations

In the mid-20th century, Harold Interlocking saw initial upgrades to support expanding commuter operations on the (LIRR) following recovery efforts. A key modification occurred on February 21, 1963, when a 5-lever Transcontrol mini-lever panel was installed alongside the existing 47-lever Model 14 electro-pneumatic machine, allowing remote of the Great Neck Interlocking and improving coordination with the original relay system. The most significant early renovation took place over nine weeks in the summer of 1990, when the entire was shut down for a comprehensive rebuild managed by , the federal successor to the for infrastructure. This upgrade replaced the aging relay-based with a microprocessor-based logic system, increasing capacity to handle surging LIRR and Transit commuter traffic while maintaining compatibility with intercity services. The project addressed operational bottlenecks from growth through enhanced signaling and track alignments. As part of the 1990 work, the original Harold Tower—dating to 1910—was decommissioned on July 1, 1990, and a new temporary tower was constructed to oversee operations during the transition. By the mid-1990s, full control shifted to remote operation from the centralized tower at , with the new Harold Tower closing on July 3, 1999, and operations integrated into the Penn Station Control Center. This decentralization improved response times and safety, building on the relay system's foundational design without requiring on-site staffing.

Improvements

East Side Access Project

The East Side Access project, initiated by the () in 2009 as a key component of the $11.1 billion initiative to extend () service to , involved extensive reconstruction at Harold Interlocking to accommodate new routing for LIRR trains. This work focused on rerouting LIRR tracks to connect with newly bored tunnels leading to the underground terminal, including the addition of storage leads for improved operational flexibility. The modifications also aimed at separating LIRR flows from operations, with bypass tunnels playing a supporting role in isolating high-speed traffic. Funding for the Harold Interlocking upgrades included a $295 million federal grant awarded in September 2011 to address congestion and enhance capacity, part of broader support for rail improvements. Overall costs for the Harold-related elements reached approximately $500 million, reflecting the complexity of reconfiguring one of the nation's busiest rail junctions while maintaining ongoing service. The reconstruction was completed on January 25, 2023, coinciding with the inaugural LIRR train arriving at , enabling the full transition of LIRR services to the new 8-track terminal. These changes significantly reduced conflicts between LIRR and trains at the , improving reliability and efficiency for both commuter and services.

Northeast Corridor Bypass

The Northeast Corridor Bypass project was initiated in 2013 under the auspices of federal planning efforts for the , with the aim of creating grade-separated paths for trains to avoid conflicts with [Long Island Rail Road](/page/Long Island Rail Road) (LIRR) traffic at the congested Harold Interlocking. This initiative sought to address chronic bottlenecks where intercity and commuter operations intersect, enhancing reliability for Amtrak's high-speed services along the corridor. Initial funding of $295 million was allocated through the High-Speed Intercity Passenger Rail program to support the development of dedicated bypass infrastructure. The project comprises two key components: the Eastbound Re-Route (EBRR), a new tunnel allowing eastbound trains to duck under LIRR tracks and bypass the interlocking, and the Westbound Bypass (WBBY), an elevated track providing a similar conflict-free path for westbound movements. The EBRR tunnel was completed and entered service in May 2025, enabling departures from Penn Station to avoid interference with incoming LIRR trains. As of November 2025, construction of the WBBY remains ongoing, with completion expected by late 2025 to further isolate operations from LIRR activity. These elements integrate briefly with the broader project tracks to support enhanced flow. Development and construction have encountered significant challenges, including delays stemming from coordination issues between and the , which jointly manage operations at Harold Interlocking. Interagency disputes over scheduling and design specifications stalled progress after initial work began in , contributing to timeline extensions. Costs for the Harold improvements escalated notably, rising from an estimated $222 million to $500 million by due to scope changes and site complexities, with further increases in overall costs due to coordination hurdles at Harold, contributing to project-wide overruns approaching $1 billion by 2018. By providing dedicated routes, the bypass enables trains to traverse the area without the current 30 mph speed restrictions imposed by the interlocking's switches and crossings, thereby improving operational speeds and on-time performance. This separation reduces conflicts with LIRR services, alleviating major delays for Northeast Corridor runs between and and supporting more reliable intercity travel times. Overall, the project enhances capacity at one of the nation's busiest rail junctions, minimizing disruptions for up to 250,000 daily passengers on affected lines.

Interlocking Modernization

The modernization of Harold Interlocking focused on upgrading its control and safety systems to enhance operational reliability and safety, separate from physical track rerouting efforts. In 2018, the () completed a major replacement of the signal system, transitioning from a traditional hard-wired, relay-based setup to a microprocessor-based with built-in redundancies designed to improve movement efficiency and reduce failure risks. This upgrade incorporated advanced features such as (PTC), which was fully implemented at the interlocking in late 2020 as the final segment for the (LIRR), enabling automated enforcement of speed restrictions and route protections to prevent collisions and derailments. The system also supports through real-time data collection, allowing and LIRR to anticipate equipment issues across the (NEC) and minimize disruptions. Automated routing algorithms within the framework facilitate dynamic switch and signal management for the high-volume traffic at this junction. The project was funded as part of broader infrastructure investments, including a $2.45 billion federal loan package announced in 2016 to support signaling and control enhancements along the corridor, addressing aging systems that contributed to approximately 26% of delay minutes in 2022. Initial planning and preparatory work for the signal upgrades began around 2017, with full operational testing and integration extending through 2020 for PTC, and ongoing refinements tied to NEC-wide improvements planned through 2029. Looking ahead, the modernized interlocking is scalable to support future high-speed rail initiatives on the , with compatibility for increased train frequencies and speeds. The system now enables remote monitoring and control from facilities like Penn Station, optimizing daily operations without on-site manual interventions.