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For the body-less truck chassis see: Rolling chassis

Santa Fe EMD FP45

A cowl unit is a diesel locomotive with full-width, enclosing bodywork, similar in appearance to the cab unit-style of earlier locomotives, such as the EMD F-units of the 1940s and 1950s.  The term cowl unit is of North American origin, although similarly-styled locomotives exist elsewhere.

Unlike a cab unit, whose body is both an enclosure and the main structural member of the locomotive, a cowl unit’s bodywork acts only as a enclosure—the body plays no structural role.  Structural support for the locomotive’s machinery, as well resistance to buff and draft loads, is embodied in the locomotive's below-deck frame.  As the body itself is not structural, it can be removed from the chassis, a feature that facilitates heavy maintenance and repair.

Cowl units were originally produced at the request of the Santa Fe railway, their EMD FP45 units having a full-width “cowl” body built on a EMD SDP45 hood unit's chassis—the SDP45, in turn, was a stretched version of the EMD SD45 freight unit.  Amtrak’s SDP40F units were also cowl units, and were built up on the EMD SD40-2 freight locomotive chassis.

Most cowl units have been passenger-hauling locomotives.  In this service, the cowl unit's full-width bodywork and smooth sides match the rest of the train's general appearance, as well as facilitate decoration of the locomotive with the livery desired by passenger operators, e.g., Santa Fe’s distinctive “warbonnet” livery.  With no decking outside of the carbody, such as found on hood-style freight units, a cowl unit’s design tends to discourage unwanted riders.  Furthermore, the smooth outline of the locomotive allows it to be run through the same wash racks used to clean passenger cars.

The main disadvantage of the cowl unit is low rear visibility from the cab. The EMD SD50F and SD60F, GE C40-8M and BBD HR-616 were given a Draper Taper (named after its creator, William L. Draper, a former Canadian National assistant chief of motive power), in which the body is narrower immediately behind the cab, and gradually widens further aft, although the roof remains full-width the length of the locomotive.  This arrangement improves rearward visibility to some extent, but such locomotives cannot run in reverse as the lead unit because they do not have ditch lights at both ends.

Passenger-oriented cowl units

[edit]
Amtrak EMD F40PH

Freight-oriented cowl units

[edit]
EMD F45

Export/license-built cowl units

[edit]
Pacific National EMD AT42C in Australia

LMS 10000 & 10001

[edit]

The LMS Diesels 10000 & 10001, later classified as British Rail Class D16/1, were introduced in 1947.  These were Great Britain's first mainline diesel locomotives, coming about a decade after America's first cab units.  Despite their streamlined exterior, the LMS units are actually cowl units.  It is easy to misinterpret this, because as in North America, cowl designs tend to be more angular in appearance, while cab designs have a similar curved streamlining.

References

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Cowl unit

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A cowl unit is a diesel-electric locomotive body style characterized by a full-width, non-load-bearing carbody that encloses the engine, electrical systems, and other components, providing protection while relying on a heavier underframe for structural support and weight distribution.[1] This design differentiated cowl units from earlier cab units, such as the EMD F-series built from the late 1930s to the 1950s, where the carbody itself contributed to the locomotive's structural integrity.[1] The first production cowl units were EMD's FP45 and F45 models introduced in 1967–1968.[2] Introduced in the late 1960s by major manufacturers including Electro-Motive Diesel (EMD) and General Electric (GE), cowl units represented an evolution in locomotive architecture, prioritizing easier maintenance access and a streamlined appearance without compromising the frame's load-bearing role.[1] Cowl units gained prominence in North American railroading, with both freight-oriented cowl unit models (like EMD's SD40-2F, SD50F, and SD60F) and passenger variants featuring wide-nose safety cabs for improved crew visibility and protection.[2] They were especially valued on Canadian railroads, such as Canadian National (CN) and Canadian Pacific (CP), for their enclosed cowling that buffered against extreme cold, with GE's C40-8M (built 1990–1994) marking the last major production run of 84 units tailored for such conditions.[3] However, by the 2010s, many cowl units began facing retirement due to challenges like hot operating cabs and reduced visibility compared to modern wide-cab hood units, with ongoing retirements continuing into the 2020s; for example, CN placed 19 of its 55 C40-8M locomotives up for sale in 2020, and service in certain roles ended by 2024.[3][4]

Overview

Definition

A cowl unit is a body style of diesel locomotive featuring full-width, enclosing bodywork referred to as a "cowl," which serves as a non-load-bearing shell mounted on a separate underframe or chassis that provides the primary structural strength.[5][1] This design contrasts with locomotives that incorporate load-bearing bodywork integral to the overall frame.[1] The term "cowl unit" originated as a primarily North American designation in the late 1960s to describe this configuration, though similar full-width, non-structural body styles exist in other regions under different nomenclature.[6][2] Structurally, the cowl spans the locomotive's entire width, creating a streamlined exterior while encasing internal components such as the diesel engine, generators, and other power plant elements within the non-structural enclosure.[5][7] This approach differentiates cowl units from hood units, which employ narrower, load-bearing hoods as part of the topside structure, and from earlier cab units like the EMD F-series, where the full-width body forms an integral, structural component rather than a detachable cover.[7][1]

Key characteristics

The cowl unit features a full-width enclosing bodywork that aligns visually with passenger car profiles, creating a unified and streamlined appearance for mixed consists. This design often incorporates matching liveries across the trainset, such as the Atchison, Topeka and Santa Fe Railway's iconic red-and-silver "warbonnet" scheme applied to its FP45 locomotives.[2] Operationally, cowl units emphasize accessibility and crew protection through removable non-structural panels on the body shell, allowing straightforward maintenance without compromising the underlying frame. Unlike traditional hood units, they lack external walkways or decking, instead providing an internal walk-through engine room that enables en-route inspections and repairs in adverse weather conditions, enhancing safety for personnel.[2][8][9] Mechanically, these locomotives integrate power systems onto standard hood unit chassis, such as the Electro-Motive Division (EMD) SD-series underframe, with the cowl serving as an added shell rather than a load-bearing component. Horsepower ratings typically range from 3,000 to 4,000 hp, mirroring those of their hood counterparts due to shared diesel-electric propulsion.[2][8][10] The design evolved in the 1960s as a cost-efficient adaptation of open hood units, where enclosing cowls were fitted to existing chassis to avoid the expense of redesigning the underframe while achieving a more enclosed profile.[2]

History

British prototypes

The London, Midland and Scottish Railway (LMS) constructed the prototypes numbered 10000 and 10001 at its Derby Works as mixed-traffic diesel-electric locomotives, with 10000 emerging in December 1947 and 10001 completing trials in April 1948.[11] These were the first mainline diesel locomotives built in Great Britain, designed under the direction of Chief Mechanical Engineer H. G. Ivatt in collaboration with English Electric, who provided the engines, generators, and traction motors.[12] Post-nationalization in 1948, they were classified by British Railways as Class D16/1.[12] Each locomotive featured a 1,600 hp (1,193 kW) net output English Electric 16SVT sixteen-cylinder diesel engine driving a DC generator to power six traction motors on a Co-Co bogie arrangement, enabling a top speed of 93 mph (150 km/h) and a maximum tractive effort of 41,400 lbf (184 kN).[13] The body adopted an innovative full-width enclosing structure divided into three sections—cabs at both ends with triple windscreens and a central engine/generator compartment—built from heavy-gauge steel 'I'-section girders, sheet steel decking, and internal asbestos insulation for weather protection and component access.[11] This cowl-style design, where the non-load-bearing body provided aerodynamic streamlining and facilitated maintenance, represented Europe's earliest implementation of such a configuration on a mainline diesel.[1] The locomotives were intended for paired operation on principal expresses and single use on freight, incorporating Clarkson steam generators for train heating.[11] Following modifications in late 1948 to address early service experience, such as improved cooling and control systems, the pair entered regular service in 1949, allocated to Derby Friary depot on the London Midland Region.[11] They hauled key expresses including the London St Pancras to Manchester and later the Southern Region's Royal Wessex, alongside freight duties, demonstrating reliable performance over nearly two decades despite the experimental nature.[11] No. 10000 was withdrawn in December 1963, followed by No. 10001 in June 1966, as part of British Railways' fleet modernization favoring newer Type 4 designs; both were scrapped in 1968 at Cashmore's, Great Bridge, and Cox & Danks, Old Oak Common, respectively, before the diesel preservation era began.[14] Although not mass-produced, the LMS Twins served as conceptual precursors to subsequent British mainline diesels, including the influential English Electric Type 4 (Class 40), by validating the practicality of high-power diesel-electric traction and the enclosing body for operational efficiency in Britain's temperate climate.[15] A faithful recreation of No. 10000 is under construction by the Ivatt Diesel Re-creation Society using an original 16SVT engine and a modified Class 58 underframe, aimed at heritage operations.[16]

North American adoption

The adoption of cowl units in North America began with the introduction of the Electro-Motive Diesel (EMD) FP45, the first commercial model of its kind, ordered by the Atchison, Topeka and Santa Fe Railway and delivered starting in December 1967 for use on flagship passenger trains such as the Super Chief and El Capitan.[17] This marked a shift from earlier cab units, as railroads sought modern diesel power that could integrate seamlessly with streamlined passenger consists while addressing the transition away from steam locomotives and aging early diesels. Production of cowl units surged during two key periods: 1968–1974, encompassing models like the EMD F45 (86 units built for freight service on roads including Santa Fe and the future Burlington Northern) and the EMD SDP40F (150 units produced 1973–1975), and 1981–1994, which included extended runs of passenger-oriented variants such as the EMD F40PH (over 325 units built, primarily for Amtrak and commuter operators).[2][17][18] Market drivers for this expansion were rooted in the needs of passenger railroads to maintain visual and operational harmony between locomotives and cars, particularly as intercity services faced competition and regulatory changes. The formation of Amtrak in 1971, which centralized U.S. passenger rail operations and inherited a patchwork fleet, accelerated demand for purpose-built power; the SDP40F, Amtrak's first entirely new locomotive acquisition, exemplified this push to modernize long-distance routes with reliable, aesthetically cohesive units.[18] By the late 1970s, commuter rail growth further boosted orders, with the F40PH becoming a staple for services like those of Metra and GO Transit. Electro-Motive Diesel initially dominated production, delivering the majority of early cowl units including the FP45, F45, SDP40F, and F40PH series, which accounted for hundreds of examples tailored to both passenger and freight applications. General Electric entered the market with the P30CH (25 units built 1975–1976 for Amtrak) and later the C40-8M (84 units produced 1990–1994: 55 for Canadian National, 26 for BC Rail, and 3 for Quebec North Shore and Labrador Railway), while Bombardier Transportation contributed the HR-616 (20 units for Canadian National in 1982), introducing distinctive features like the Draper Taper for enhanced crew visibility. Overall production exceeded 1,000 units across variants by the mid-1990s, reflecting widespread Class I railroad uptake for services blending passenger aesthetics with diesel efficiency.[2][19][20] Adoption waned from the 2000s onward as railroads prioritized multi-engine hood units for improved fuel efficiency, maintenance access, and emissions compliance in an era of freight dominance and electrified passenger corridors. By the 2020s, retirements accelerated, including Canadian National's auction of 19 C40-8M units in 2020; as of 2025, a few ex-BC Rail C40-8Ms remain in service on CN, though most have been retired, signaling the end of significant cowl unit fleets on major carriers with few new builds after 1994.[2][3][21]

Design features

Advantages

The non-structural cowl design of cowl units facilitates maintenance by allowing the entire bodywork to be fully removed from the underframe for major repairs, providing unobstructed access to internal components without the need to disassemble the chassis. This feature streamlines heavy overhauls and inspections, reducing downtime compared to integral body designs. Additionally, internal walkways within the enclosed structure enable crew members to move between the cab and engine room without external exposure, enhancing accessibility during routine checks or adjustments.[8] The cowl unit's full-width bodywork integrates seamlessly with passenger car consists, creating a uniform train appearance that enhances aesthetics and operational cohesion. This design contributes to reduced aerodynamic drag at typical passenger speeds, improving fuel efficiency over hood units with similar power ratings. Furthermore, the smooth, enclosed exterior allows cowl units to pass through standard passenger car wash facilities more effectively than hood units, whose protruding walkways and inset sides complicate cleaning and can trap debris.[22] Safety benefits arise from the enclosed body, which deters trespassers and vandalism by eliminating external walkways and access points common to hood units, thereby reducing unauthorized entry risks. The fully covered design also provides superior protection for vital components against weather elements like rain, snow, and debris, minimizing corrosion and extending equipment longevity. Crew comfort is notably improved in adverse conditions, as the enclosed interior shields personnel from cold, wind, and precipitation during on-board tasks.[6] Cowl units leverage proven freight locomotive chassis, such as those from established hood unit platforms, which lowers development and production costs by avoiding the need for entirely new structural engineering. This approach enables manufacturers to adapt reliable mechanical foundations for passenger service with minimal redesign. For instance, the EMD F40PH, a prominent cowl unit model, has demonstrated exceptional durability, with many units achieving over 40 years of service on railroads like Metra through routine maintenance and targeted upgrades.[23]

Disadvantages and modifications

One significant limitation of cowl units is their poor rearward sightlines, resulting from the full-width enclosing bodywork that obstructs the engineer's view to the rear, thereby elevating collision risks during reverse movements or switching operations.[3] This issue is exacerbated in bi-directional operations, where modern cab designs prioritize forward visibility, often necessitating engineers to lean out of side windows or rely on supplementary aids like mirrors for adequate rear observation.[24] To address rear visibility concerns without fully compromising the aesthetic and protective benefits of the cowl design, the Draper Taper modification was introduced in the 1980s. Named after Canadian National's chief motive power officer William L. Draper, this adaptation featured a tapered rear section of the cab roof, angling inward more than 10 feet behind the cab on locomotives such as the EMD SD50F (built 1985–1987 for CN), allowing crews better aft sightlines while preserving engine compartment access.[25] Similarly applied to models like the GE C40-8M and Bombardier HR616, the Draper Taper represented a targeted engineering solution to balance safety and the enclosed carbody style, though early implementations like the HR616 still encountered mechanical reliability challenges leading to early retirements.[25] Additional drawbacks include elevated initial construction costs attributable to the extensive bodywork needed for the full enclosure, as well as restricted access to roof-mounted components such as cooling systems, which complicates maintenance compared to open hood units.[26] Enclosed spaces in cowl units can also promote corrosion if moisture accumulates, requiring vigilant inspections and protective treatments.[27] Post-1980 engineering adaptations further mitigated visibility limitations through features like expanded windshield areas and more forward cab positioning to optimize forward and lateral fields of view, aligning with ergonomic guidelines recommending at least 180° lateral visibility and clear sightlines to track-level objects up to 50 feet ahead.[24] For example, the GE P40DC passenger locomotive incorporated a rear hostler's window and stand, enabling operation from the opposite end with enhanced reversing capabilities, while its slanted nose design improved both aerodynamic efficiency and overall sightlines.[28] These updates reflect broader efforts to adapt cowl configurations for safer, more versatile operation in diverse rail environments.[29]

Types

Passenger-oriented cowl units

Passenger-oriented cowl units are diesel-electric locomotives designed primarily for hauling passenger trains, featuring streamlined cowling that covers the underframe for improved aesthetics and aerodynamics in commuter and intercity services. These units prioritize reliability, crew comfort, and integration with passenger car systems over high-speed performance, making them suitable for push-pull operations where the locomotive can operate in either direction without turning. The Electro-Motive Division (EMD) F40PH stands as the most prominent example, a 3,000 horsepower (2,200 kW) locomotive built between 1975 and 1988, with over 400 units produced mainly for Amtrak and GO Transit in Canada. Equipped with a 16-cylinder EMD 645F3B prime mover, the F40PH was engineered for dependable service on routes like the Northeast Corridor, where it powered trains at speeds up to 110 mph (177 km/h). Another early model, the SDP40F, delivered 3,000 horsepower (2,200 kW) and was constructed from 1973 to 1974 exclusively for Amtrak, with 150 units built on an SDP40 chassis adapted for passenger use; these were tested on the same corridor but faced truck-related derailment issues at high speeds, leading to their withdrawal by the late 1970s.[30] In service history, these cowl units were integral to push-pull operations across the United States and Canada, allowing cab cars at the opposite end of the train to control the locomotive remotely, enhancing efficiency on electrified and non-electrified lines. Amtrak's F40PH fleet, numbering 216 units, dominated passenger hauling through the 1980s and 1990s on routes including the Auto Train and California Zephyr, though most were retired by the early 2000s in favor of newer locomotives; several have been preserved in museums or repurposed for excursion service. The SDP40F's brief tenure highlighted early challenges in cowl unit stability, but it paved the way for refinements in subsequent designs.[31] Design adaptations for passenger service include head-end power (HEP) generators, typically rated at 500 kW, which supply electricity for lighting, air conditioning, and other amenities in trailing passenger cars, eliminating the need for separate generator cars. Full-width cabs provide enhanced crew comfort with improved visibility and space compared to freight-oriented hood units, while the overall production of passenger cowl units like the F40PH totaled approximately 500 across variants, emphasizing durability for frequent starts and stops rather than sustained high speeds. These features contributed to a sleek appearance that aligned with the aesthetic advantages of cowl designs for passenger trains. The operational legacy of passenger-oriented cowl units is profound, as they dominated North American passenger railroading from the 1970s to the 1990s, with the F40PH becoming synonymous with Amtrak's identity and influencing rebuild programs by MotivePower Industries (MPI), which upgraded dozens of units with modern electronics and emissions controls; as of 2025, over 50 MPI-rebuilt F40PHs remain in active service for commuter railroads like Metrolink and Caltrain. This enduring influence underscores their role in bridging mid-20th-century diesel technology with contemporary passenger demands.

Freight-oriented cowl units

Freight-oriented cowl units were designed primarily for heavy-haul freight service, featuring robust construction to handle substantial loads while retaining the streamlined, full-width bodywork originally developed for passenger locomotives. These units combined the aesthetic and protective qualities of cowl designs with enhanced structural reinforcements suitable for freight operations, such as thicker frames capable of supporting loads exceeding 100 tons per unit. Multi-unit lashups were standard, allowing several locomotives to operate in tandem for powering long, heavy trains across demanding terrains. The cowl enclosure also offered superior weather protection for crews on extended hauls, reducing exposure to harsh conditions compared to traditional hood units.[2] A prominent example is the Electro-Motive Division (EMD) F45, a 3,600 horsepower six-axle diesel-electric locomotive produced from 1968 to 1970. Built specifically for freight, the F45 featured an EMD 20-645E3 prime mover and was acquired by the Atchison, Topeka and Santa Fe Railway (40 units, numbered 1900-1939) and, through mergers, the Burlington Northern (46 units originally from Great Northern and Northern Pacific), totaling 86 units. These locomotives served in mixed freight and occasional passenger duties on lines like the Santa Fe's transcontinental routes, hauling bulk commodities such as grain and coal through varied landscapes including deserts and mountains. Many F45s remained in service into the 2000s, with some rebuilt to extend their operational life.[17][17] In Canada, General Motors Diesel (GMD) produced cowl units tailored for northern freight operations, including the SD40-2F for Canadian Pacific (CP) Railway, a 3,000 horsepower model built from 1988 to 1989 with 25 units (numbered 9000-9024). Although similar designs were explored for Canadian National (CN), CP's SD40-2F exemplified adaptations for prairie and mountain runs, where the cowl improved crew comfort in extreme weather. For CN, the GMD SD50F (60 units, 3,600 horsepower, built 1984-1985) and SD60F (64 units, 3,800 horsepower, built 1990-1991) filled similar roles, focusing on heavy freight across the prairies and Rockies. The GE C40-8M, a 4,000 horsepower Dash 8-series cowl unit built from 1990 to 1994, had total production of 84 units, with an original order of 55 for CN (numbered 2400-2454); CN's effective fleet grew to 81 units after acquiring 26 from BC Rail in 2004, emphasizing high-traction performance for unit trains of grain, potash, and intermodal cargo. These Canadian units often operated in lashups of three or more for mountain grades.[32][33][34][35] Service histories highlight the versatility of these units, with Santa Fe's F45s contributing to postwar freight booms until retirement in the late 1990s. CN's cowl fleet, including the C40-8M, was concentrated on transcontinental lines through the prairies and Canadian Shield mountains, supporting bulk commodity transport. Retirements accelerated in the 2010s due to emissions regulations and fleet modernization; CN began retiring its C40-8M units in the 2010s, auctioning 19 in 2020, with one remaining active in yard service as of September 2024 and full retirement likely by 2025. Overall production of major North American freight cowl units from the 1960s to 1990s exceeded 200 examples across models, though exact totals vary by inclusion of rebuilds. Many surviving units, such as select F45s and SD50Fs, were rebuilt to standard hood configurations like the SD40-2 for continued freight use, underscoring their role as a transitional design blending passenger-era styling with freight reliability during the late 20th century.[2][3][35][17][32]

Export and license-built cowl units

The export and license-built cowl units adapted the North American design for international freight applications, incorporating modifications for local gauges, climates, and operational demands. A key model is the EMD GT42CU, rated at approximately 3,000 horsepower from its 12-cylinder EMD 710-series engine, which was produced in the 1990s and early 2000s under license by Clyde Engineering and its successor Downer EDI Rail in Australia. These locomotives were built primarily for railroads such as Pacific National and Queensland Rail, with total production reaching 193 units (GT42CU AC: 61 units built 1999–2005; GT42CU ACe: 132 units built 2007–2013) for 1,067 mm (3 ft 6 in) narrow-gauge operations across various Australian operators.[36] In service, these units have been employed mainly for heavy freight haulage on Australia's narrow-gauge networks, including coal and intermodal trains, where their full-width cowl body provided improved aerodynamics and crew protection compared to traditional hood designs. Overall production of export cowl units exceeded 200 units globally across models, primarily the Australian GT42CU series, facilitated by license agreements with firms such as Morrison Knudsen for assembly and customization in target markets; post-LMS era developments saw no significant European exports.[37][38] As of 2025, GT42CU units continue to operate reliably in Australia for freight duties, contributing to the evolution of hybrid locomotive concepts through their modular cowl architecture, though international adoption has shifted toward conventional hood units for cost and maintenance advantages.[39]

References

  1. What is a Cowl Unit? - Santa Fe Subjects
  2. End of the Line for Canadian 'Cowl' Units?
  3. Rail glossary - Translation Directory
  4. Cowl unit | Locomotive Wiki - Fandom
  5. A diesel locomotive's family tree - Trains Magazine
  6. Cowl locomotives in North America - Trains Magazine
  7. Question about cowl units - Locomotives - Trains.com Forums
  8. [PDF] HO EMD FP45 Diesel Locomotive - Santa Fe - Athearn
  9. FP45 - RailroadfanWiki
  10. [PDF] Early Main Line Diesel Locomotives of British Railways
  11. BR Class D16/1 LMS 10000 Sound Projects - Digitrax, Inc.
  12. British Rail Class D16/1 Facts for Kids
  13. the history of 'the twins' - Ivatt Diesel Recreation Society
  14. Ivatt Diesel Recreation Society - Recreating LMS 10000
  15. LMS10000 project buys two more English Electric power units
  16. EMD "F45"/"FP45" Locomotives: Specs, Roster, History
  17. Amtrak SDP40F diesel locomotives - Trains Magazine
  18. EMD "F40PH" Series: Specs, Roster, History - American-Rails.com
  19. Amtrak GE P30CH locomotive - Trains Magazine
  20. https://www.railroad.net/why-so-few-hood-units-for-passenger-trains-t155154.html
  21. Metra marks 40 years of F40PH locomotives' service
  22. [PDF] Human Factors Guidelines for Locomotive Cabs
  23. HR616 "Draper Taper" Locomotives: Specs, Models, Background
  24. Draper Tapers, Cowl Bodies, and Saftey Cabs - Trains.com Forums
  25. Draper Taper - The Diesel Shop
  26. [PDF] Amtrak - P40DC - Athearn
  27. GE "Genesis" Series Locomotives: Data, Specs, Roster
  28. EMD "SD40" and "SD40-2" Locomotives: Data, Rosters, Specs
  29. EMD "SD50" Locomotives: Data Sheet, Specs, Roster
  30. GE "C40-8" and "C40-8W" Locomotives: Data Sheet, Specs, Roster
  31. Canadian National cowls: Where are they now? - Trains Magazine
  32. Downer EDi Rail GT42CU AC and GT42CU ACe - loco-info.com
  33. EMD® GT42AC - Progress Rail
  34. EMD and Barloworld form African locomotive joint venture | News
  35. Morrison-Knudsen locomotives - The Diesel Shop
  36. Export Locomotives - The Diesel Shop
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