Fact-checked by Grok 2 weeks ago

Bogie exchange

Bogie exchange is a method designed to facilitate the transfer of , such as wagons and locomotives, across networks with differing gauges by replacing the bogies—the assemblies consisting of wheels, axles, and frames—with compatible ones for the new . This technique addresses breaks of gauge, where widths vary, such as between the 1,600 mm broad gauge and 1,435 mm standard , preventing the need for complete unloading and reloading of cargo. Primarily used in freight operations, it enables efficient cross-border or inter-regional without extensive infrastructure overhauls. The process of bogie exchange typically occurs at specialized facilities equipped with lifting mechanisms, where the rail vehicle is raised using hydraulic jacks or other hoists to detach the existing bogies, which are then swapped out for pre-positioned alternatives via cranes or transfer systems before the vehicle is lowered onto the tracks and reconnected. This can be manual or semi-automated, handling multiple vehicles per shift, though it requires sidetracks, storage for spare bogies, and skilled labor to ensure alignment and safety. In modern systems, underfloor lifting installations allow for simultaneous exchanges on several bogies, minimizing during or transitions. Historically, bogie exchange emerged in the mid-19th century amid widespread gauge inconsistencies caused by fragmented railway development, particularly in following the Railway Regulation (Gauge) Act of 1846, which standardized much of the network but left legacy breaks. By the , it became one of the most common adapter technologies in , the , and colonial networks like , where multiple gauges led to over 50 transshipment points by 1947, reducing costs and delays compared to full track conversions. In the U.S., it supported integration after the "Great Gauge Change" of 1886, which aligned Southern tracks to standard gauge and boosted rail traffic by 50%. Today, bogie exchange remains in use in regions with persistent gauge differences, such as at Eurasian borders including China-Kazakhstan (Alashankou) and Russia-China (Zabaikalsk), where it supports international freight corridors to and beyond, including routes toward . While advantageous for its relatively low capital cost and ability to maintain wagon integrity, the method can be labor-intensive and limited by yard capacity and bogie inventory. Advancements in continue to enhance in global rail logistics.

Definition and Purpose

Definition

Bogie exchange is a railway operation technique that enables the adaptation of to different by detaching and reattaching bogies, which are the wheeled undercarriages supporting the body. This method is primarily employed at break-of-gauge locations, such as international borders, to allow seamless continuation of services without unloading or passengers. By swapping the entire bogie assembly, including axles and wheels calibrated to the specific gauge, the process avoids the need for full , thereby reducing handling times and costs associated with gauge incompatibilities. The core components of a bogie exchange system include the bogies themselves, which consist of wheelsets, , and elements; lifting or pits to elevate the vehicle ; tools for precise positioning; and tables or cranes to maneuver the bogies in and out. Lifting , often portable and hydraulic or mechanical, support the weight of the laden , typically up to several hundred tons, while ensuring during the swap. tools and mechanisms, such as side shifters or cranes, facilitate the horizontal movement of bogies along dedicated tracks or aisles, maintaining compatibility with the vehicle's underframe connections. In basic , the process begins with positioning the railway vehicle over the exchange facility, where raise the body to clear the bogies from the rails, usually by 900 mm or more for clearance. Brake rods and electrical connections are disconnected, allowing the old bogies—matched to the originating —to be slid out via transfer tables. New bogies, pre-assembled for the destination , are then aligned, inserted, and secured to the underframe, followed by lowering the body, reconnection, and testing for operational integrity. This sequence typically occurs wagon-by-wagon in a train consist, minimizing . Common applications involve gauge transitions such as the standard 1,435 mm gauge to the 1,520 mm gauge, frequently at Euro-Asian borders to support cross-continental freight and passenger services. Other examples include exchanges between 1,600 mm broad gauge and 1,435 mm standard gauge in Australian networks, handling high-volume interstate traffic at facilities like . Transitions from 1,000 mm meter gauge to 1,435 mm standard gauge also occur in select operations, such as in parts of and , to integrate narrow-gauge lines with broader systems.

Historical Context and Reasons for Use

Bogie exchange emerged as a practical solution to gauge incompatibility in the mid-to-late , particularly in where varying track s proliferated due to companies' independent developments, such as Isambard Kingdom Brunel's 7 ft (2140 mm) broad gauge versus the emerging 4 ft 8½ in (1435 mm) standard . By the , as gauge breaks caused significant delays and costs in transshipping goods, bogie exchange became one of the most common adapter technologies, involving the lifting of rail cars to swap undercarriages for compatible gauges using steam-powered hoists. This method addressed the economic inefficiencies of the "railway gauge muddle," a legacy of policies that prioritized local interests over national standardization, though it remained labor-intensive and prone to operational bottlenecks. The primary motivations for bogie exchange stemmed from colonial and imperial legacies that entrenched incompatible gauges across borders, such as the British standard of 1435 mm in much of and former colonies versus the Empire's 1524 mm (5 ft) gauge, chosen in 1843 and first used on the St. Petersburg–Moscow Railway, which opened in 1851. In , differing state gauges—broad 1600 mm in and standard 1435 mm for interstate lines—necessitated facilities like the one at , established around 1960 to connect with South Australian networks, enabling efficient east-west freight movement without full unloading. Similarly, in and Asia, cross-border traffic between standard-gauge and -gauge countries drove adoption to avoid the high costs and disruptions of complete , especially for bulk goods and passengers where maintaining train integrity was crucial. The gauge was later narrowed to 1520 mm in 1970 for improved stability. Post-World War II, bogie exchange evolved from manual processes to mechanized systems, particularly in the 1950s-1970s amid Cold War-era trade. A notable example is the Erenhot-Zamin-Uud border facility between China (1435 mm) and Mongolia (1520 mm), operational since the 1956 completion of the Ulaanbaatar Railway as a Soviet-Mongolian-Chinese joint project, which facilitated resource exports like minerals while preserving cargo for perishable or high-value shipments. This shift improved efficiency over alternatives like reloading, reducing turnaround times from days to hours and minimizing damage to goods, though early implementations faced challenges including labor disputes over hazardous lifting tasks, weather-induced delays in outdoor operations, and safety risks from heavy machinery accidents. By the mid-20th century, these systems underscored economic imperatives in divided rail networks, prioritizing continuity over costly gauge conversions.

Technical Methods

Lifting and Exchange Process

The bogie exchange process involves a structured workflow to facilitate the adaptation of rail vehicles to different track gauges by replacing the undercarriage assemblies. Preparation begins with positioning the vehicle precisely over the exchange facility, such as a pit or lifting table, ensuring stable alignment with the track using guide rails or markers. Disconnections follow, including the release of brake rods, traction motors, and other linkages between the car body and bogies to allow safe separation. The car body is then lifted using hydraulic jacks or portal systems, distributing the load evenly across support points to prevent structural stress. Once elevated, the existing bogies are removed by rolling or shifting them laterally via cranes, tugs, or transverse movers, clearing space for the insertion of new gauge-compatible bogies positioned with precision to match the vehicle's centerline. The new bogies are slid into place, and the car body is lowered onto them, followed by reconnection of all mechanical and electrical components. Final testing verifies operation, electrical integrity, and overall stability before the vehicle is moved out for operational use. Facilities for bogie exchange vary between pit-based underfloor systems, where lifting occurs from below the tracks via embedded jacks and rail bridges, and above-ground setups using elevated rails or drop tables that avoid deep excavations and confined spaces. Alignment is critical in both types to ensure precise matching and prevent operational issues, often achieved through adjustable platforms or mechanical guides that position bogies within millimeters of the required . Safety protocols are integral throughout, including the placement of wheel chocks or blocks to immobilize the vehicle and prevent unintended movement, coordinated crew signaling, and the use of hydraulic rated for loads up to tonnes per unit or higher for heavy locomotives, with overload mechanisms. Workers maintain safe distances from zones, and auto-locking features on jacks secure the load during handling. The process typically requires 6-8 minutes per , though times can extend to 60-90 minutes for entire depending on facility, automation, and vehicle type. Common errors, such as misalignment that could lead to risks during subsequent travel, are mitigated through precise positioning aids and post-exchange inspections.

Raising Procedures

The raising procedures in bogie exchange focus on safely elevating the rail vehicle body to provide clearance for bogie removal, typically achieving 1-2 meters of height to facilitate maneuvering. Primary methods utilize hydraulic jacks positioned at bolster points or dedicated jacking plates on the underbody, distributing the load evenly across multiple points. Jack capacity is determined by dividing the total vehicle weight by the number of lift points; for instance, a 80-tonne vehicle lifted at four points requires jacks rated at least 20 tonnes each to account for safety margins. Alternative approaches include scissor lift platforms integrated into track systems or gantry cranes with mobile support frames for overhead lifting. The process follows a structured sequence to ensure and precision. First, the is secured in over the exchange pit or elevated track using brakes and chocks. Next, utilities such as brake rods, air hoses, and electrical connections are disconnected to isolate the s from the body. The lifting then proceeds incrementally: jacks or platforms are activated in unison to raise the body gradually, monitoring for stability until the desired clearance is reached. Finally, the elevated body is transferred to trestles or mobile gantries for stable support, preventing reliance on the lifting equipment during the subsequent bogie swap. Advanced equipment enhances efficiency, particularly underfloor lifting installations like Windhoff systems, which employ hydraulically driven tables embedded in the trackbed to lift and support multiple bogies simultaneously. These setups, often featuring eight or more cantilever jacks, allow for rapid elevation without deep pits, reducing setup time in high-volume operations. Regional variations reflect technological evolution; in older facilities, such as those at Soviet borders like Kuźnica, hydraulic platforms were used to lift the train body approximately 2 meters before supporting it on stable structures. Modern installations, by contrast, favor automated hydraulic or electro-mechanical systems for greater speed and reliability. Key risks involve hydraulic failure, which could cause partial collapse, or uneven lifting leading to body tilt and structural stress. Mitigation relies on synchronized controls, including PLC-based feedback sensors and valves that adjust pressure in real-time across all points to maintain level elevation.

Lowering Procedures

The lowering procedures in bogie exchange involve a controlled descent of the rail vehicle body onto the newly installed s, ensuring precise to prevent structural damage or operational faults. This phase typically employs hydraulic systems for gradual lowering, allowing operators to align critical components such as center pins and bolsters before full weight transfer. Hydraulic controls enable incremental adjustments, maintaining vehicle levelness throughout the process to achieve tolerances as tight as <1 mm in bogie positioning relative to the body. The step-by-step process begins with the removal of temporary trestles or support stands that held the vehicle body during the exchange. The body is then lowered incrementally—often in stages of several centimeters—using synchronized hydraulic jacks or lifting tables, while levelness is monitored via plumb lines, sensors, or trammeling gauges to verify transverse, diagonal, and longitudinal alignments to tolerances within a few millimeters. Once alignment is confirmed, systems such as brake rigging and electrical connections are reattached, followed by a static load test to verify even weight distribution across the bogies. Equipment utilized mirrors that for raising, including portal-style hydraulic jacks with capacities up to 50 tons per and underfloor lifting installations, augmented by alignment jigs such as roller mechanisms or hoisting structures to guide the descent and ensure alignment of center pins and bolsters. These jigs facilitate fine adjustments during lowering, preventing deviations that could compromise stability. A common issue during lowering is bogie misalignment, which can cause between the body and bogie frame, leading to uneven load transfer or assembly stress. This is typically resolved through adjustable shims inserted at interfaces to correct offsets, ensuring the bogies seat properly without excessive force. Post-lowering checks include comprehensive tests to confirm functionality under load, along with verification using specialized tools to ensure the new bogies conform to the target track width. These verifications, often incorporating static load simulations, confirm the vehicle's readiness for movement prior to final release.

Adaptations for Locomotive Types

Bogie exchange for was rare compared to its use for wagons, due to the complexity of disconnecting integrated systems like pipes and handling the heavy tenders laden with and . In regions with mixed gauges, such as , multiple systems—broad (5 ft 6 in or 1,676 mm), meter (1 m), and narrow —created frequent breaks of that primarily affected freight and passenger movements, with or other methods more common for locomotives until conversions and reduced reliance on in the mid-20th century. By , meter lines accounted for 41% of the network, complicating rail operations across the subcontinent. Steam locomotives presented unique challenges during any bogie-related maintenance due to their design, including the substantial weight of tenders, which demanded reinforced capable of handling loads exceeding those for lighter . Pony trucks or trailing bogies, which provided stability on curves, were typically handled separately from leading bogies to maintain alignment. These factors made such operations notably time-intensive, often extending duration relative to exchanges on other types.

Diesel Locomotives

Diesel locomotives require adaptations during bogie exchange to accommodate their internal combustion engines and associated systems. General procedures include isolating batteries to eliminate electrical risks, draining fluids like fuel, oil, and , and supporting the heavy (typically 20 to 30 tons) with slings or additional supports during the lift to prevent structural stress. The locomotive body is raised using synchronized hydraulic jacks or overhead cranes, allowing bogies to be removed via drop tables or sideways transfer for replacement. Compared to steam locomotives, diesel designs offer greater modularity, enabling bogie swaps while retaining the engine and superstructure, which has supported cross-border freight in regions with varying gauges, such as Australia. Post-exchange, alignments are rechecked for vibration sensitivity, with torque verifications on couplings and suspension components. In hybrid diesel-electric systems, an ECU reset may be required to recalibrate controls.

Electric Locomotives

Bogie exchange for electric locomotives requires specialized procedures to manage high-voltage systems and ensure safety. Prior to lifting, pantographs are lowered and secured with locking and grounding devices to prevent contact with overhead lines or residual charge. Traction motors on the bogies are isolated by disconnecting power leads and applying lockout-tagout (LOTO) protocols to de-energize circuits, with capacitors discharged using grounding resistors. These align with standard electrical safety practices, including verification of zero voltage and grounding of non-current-carrying parts. The procedure involves isolating the main , removing motor leads, and lifting the body evenly with hydraulic jacks to swap bogies, minimizing on routes requiring gauge transitions. While bogie exchange is possible, systems are more common for seamless operations. Safety protocols include LOTO for systems like 25 , arc flash prevention training, and protective equipment. Challenges include avoiding damage to pantographs during uneven lifts, addressed with covers and alignment guides. Automated facilities support efficiency for freight and services.

Operational Aspects

Transfer Time and Efficiency

Bogie exchange operations for full trains of 20 to 30 wagons typically take 3 to 6 hours depending on length and mechanization level. These durations are derived from standard procedural steps involving lifting, bogie removal, and lowering, but vary significantly based on equipment and operational setup. Efficiency in bogie exchange is markedly improved by mechanized systems compared to methods. Labor-intensive exchanges process approximately 32 wagons per 8-hour shift, equating to about 4 wagons per hour, while automated systems achieve 56 wagons per shift, or roughly 7 wagons per hour. Mechanized approaches, such as underfloor lifting installations, enable parallel handling of multiple bogies, reducing overall time by nearly 40% for a typical 25-wagon —from 6 hours manually to 3 hours 40 minutes with . Factors influencing transfer speed include the degree of and crew expertise. Facilities with experienced teams and sheltered pits minimize variability, achieving consistent throughput even under adverse conditions. In contrast, manual processes are more susceptible to and , extending times by 20 to 50% in suboptimal scenarios. Historically, bogie exchanges often involved longer durations due to rudimentary lifting gear and sequential processing. Modern facilities, incorporating synchronized lifting and conveyor systems, have improved overall throughput to 10 to 20 vehicles per hour at high-volume borders. Optimization strategies, such as parallel bogie processing across multiple tracks, further enhance efficiency by allowing simultaneous exchanges on divided train sections, thereby cutting border dwell times and supporting faster international freight turnover. These improvements prioritize scalability for growing trade volumes without proportional increases in operational duration.

Required Equipment and Facilities

Bogie exchange operations require specialized equipment to safely lift rail vehicles, detach and attach bogies, and ensure precise alignment for different track gauges. Core components include hydraulic or electromechanical lifting jacks, which suspend the vehicle body during the process. These jacks typically have individual capacities ranging from 25 to 50 tons, with systems employing multiple units—such as 16 jacks at 25 tonnes each—to achieve total lifting capacities up to 400 tonnes for heavy locomotives or wagons. Additional essential tools encompass bogie transfer tables or rollers for moving detached bogies, often featuring adjustable drop tables suspended between rails, side shifters, or turntables to facilitate lateral or rotational positioning without manual towing. Alignment tools, such as laser systems, and torque wrenches are also utilized to verify bogie positioning and secure connections post-exchange. Facilities for bogie exchange are typically dedicated stations designed to handle the structural demands of vehicles. Traditional setups incorporate ground-level tracks with pits, allowing underfloor access for bogie detachment, while alternatives use elevated tracks approximately mm above the workshop floor to eliminate deep excavations and risks. These stations often include multiple parallel tracks for simultaneous operations. Support infrastructure, such as mobile cranes or tractors, aids in handling and storage, with a stock of standardized bogies in various gauges maintained on-site to match traffic demands. Advancements in have enhanced precision and safety in bogie exchange. Manufacturers like Andrew Engineering provide electromechanical systems with portal-style jacks and PLC-integrated controls for synchronized lifting and fault detection via visual interfaces. Similarly, Pfaff-silberblau (part of Columbus McKinnon) offers configurable bogie exchange systems, including scissor lifts, drives, and rotatable changers with hydraulic tables, supporting transverse and longitudinal movements for versatile types. These innovations reduce manual intervention, enabling faster transfers—often cutting process times compared to manual methods—while adhering to high standards. Ongoing maintenance is critical to prevent operational failures. Lifting jacks require regular calibration to ensure synchronization accuracy within ±2 mm and load-holding during power interruptions, while transfer rails and tables undergo periodic inspections for wear and alignment. Systems must comply with protocols, including ergonomic designs for worker access and features in electromechanical variants. Establishing a bogie exchange involves significant , with a proposed upgrade in the budgeted at $500,000-800,000 (equivalent to approximately $2.7-4.3 million as of 2025, adjusted for ). Ongoing operational expenses include maintenance and staffing, contributing to per-wagon costs of about $24 (1977 dollars; approximately $128 as of 2025) for manual operations.

Alternative Gauge Change Methods

Variable Gauge Axles

Variable gauge axles represent a dynamic method for adapting railway vehicles to different track gauges, enabling seamless transitions without the need for complete bogie or axle replacements. These systems feature axles equipped with sliding wheels or adjustable wheelsets that can alter their width through hydraulic or mechanical actuators, typically shifting between the Iberian gauge of 1,668 mm and the standard European gauge of 1,435 mm. In the TALGO Rodadura Desplazable (RD) system, for instance, the wheels are mounted on independent axles and can slide along the axle shaft, guided by specialized infrastructure to adjust the gauge dynamically. The operation of axles occurs on-the-move at transition points, where the reduces speed to approximately 15 km/h but does not require a or lifting. As the vehicle passes over a gauge changer facility, the wheels are unloaded and guided by converging or diverging T-shaped rails, often lubricated with for smooth movement, while the body is supported by elevated side rails to maintain . This process, which takes several minutes (typically 6-11 minutes depending on the system generation) to complete, contrasts with traditional bogie exchange methods by minimizing delays at borders. Key advantages include drastically reduced and suitability for high-speed passenger services, as the system eliminates the need for exchange pits or heavy . It enhances by allowing continuous travel across gauge boundaries, thereby lowering transshipment costs and border bottlenecks. However, limitations arise from the added complexity of , which demand higher and can introduce weight penalties from the actuators and sliding mechanisms, making these axles less ideal for heavy freight applications where under load is paramount. Recent advancements as of 2025 include efforts to extend technology to freight, such as Spain's Adif Mercave project, which is piloting adjustable axles for wagons with axleloads of 25 tonnes or more at station on the Spanish-French border, and a collaboration with to test automatic systems for cross-border freight. These developments aim to address previous limitations in heavy-load applications. A prominent example is the implementation of the RD system in Spain's high-speed network since the 1990s, facilitating uninterrupted journeys such as Madrid to (inaugurated in 1992) and Madrid to . This technology has enabled seamless connections between the and the broader rail network, for instance, allowing Barcelona-to-Paris services via the Portbou changer since 1969, with ongoing adaptations for locomotives and power cars introduced in 1999.

Axle Exchange

Axle exchange serves as a partial alternative to full replacement in gauge , focusing solely on swapping individual wheelsets while retaining the existing bogie frames. The process begins with lifting the or bogie using hydraulic jacks or underfloor systems to create clearance, allowing the old wheelset—consisting of the and fixed wheels—to be removed. Removal methods include the side-sling technique, where the wheelset is slid laterally out from under the raised using trolleys or conveyors, or the over-the-end approach, which involves tilting the bogie and pulling the longitudinally after disconnecting bearings and components. Once removed, the new wheelset calibrated to the target is inserted in reverse order, with final adjustments to ensure alignment and secure fit. This static replacement contrasts with dynamic gauge adjustment systems by requiring complete wheelset disassembly from the bogie. Key equipment for axle exchange includes hydraulic wheel presses, which apply forces up to 500 tons to dismount or mount wheels onto s if partial disassembly is needed, and axle stands or support cradles to stabilize the frame during the swap. Additional tools such as mobile lifting jacks (with capacities from 25 to 100 tons) and automated transfer trolleys facilitate safe handling, reducing manual labor and minimizing downtime. The operation typically takes 5-15 minutes per , enabling quicker turnaround compared to comprehensive exchanges that can exceed 30 minutes per unit. These systems are often integrated into workshop pits for precision control. Applications of axle exchange are primarily in workshop settings for minor adaptations or periodic , rather than rapid border operations, as it demands for lifting and precise alignment. It is especially practical for lighter vehicles, such as passenger cars or narrow-gauge conversions, where compatibility allows direct wheelset substitution without frame alterations. In mixed-gauge environments, this method supports efficient fleet adjustments during overhauls, though it is less common for heavy freight due to load-bearing constraints. The advantages of axle exchange include its relative simplicity and lower cost for vehicles with standardized designs, avoiding the need to lift entire bogies and enabling reuse of existing frames across gauges. However, it is constrained by the requirement for bogie frames to accommodate varying wheelset widths, limiting its use to compatible designs, and carries risks such as wheel or damage during forceful press-out if hydraulic controls fail or misalignment occurs. Proper and mitigate these issues, but the method demands skilled technicians to prevent hazards. Advancements in axle exchange have introduced automated changers, exemplified by Windhoff Bahn- und Anlagentechnik's wheelset exchange installations, which use programmable lifts and conveyor systems for streamlined operations in depots. Such automation reduces exchange time further and improves precision, supporting broader adoption in transitional environments.

Usage by Country

Bogie exchange was utilized in 's railway network at key break-of- locations, such as and in , to enable freight wagons to transition between standard (1,435 mm) and broad (1,600 mm) lines, with additional handling of narrow (1,067 mm) connections in the region. These facilities addressed the fragmented system resulting from separate state developments, allowing loaded wagons to continue journeys without unloading cargo. At , operations began in the 1930s and continued through the 1970s, serving as a critical link for interstate freight from the standard Trans- to the broad South network toward . The yard, spanning 3 km by 80 m, processed approximately 46,000 annually in 1975–76, doubling the volume at comparable sites like Dynon or , with a focus on general freight exceeding 770,000 tonnes that year. Manual procedures dominated, involving seven-person gangs using portable hydraulic jacks to lift , mobile cranes to swap s, and shunt tractors for positioning; the yard supported simultaneous operations on two tracks despite spatial constraints from nearby . Average transit time through the facility was 27.4 hours in 1976, influenced by marshalling, congestion, and bogie availability, though service time per was estimated at 6–8 hours. Peterborough's exchange yard, established in 1970 following the of the east-west line to standard gauge, functioned as one of Australia's two triple-gauge junctions, accommodating narrow, , and standard gauges for efficient transfers. It adapted to heavy mineral transport by converting 100 narrow-gauge ore wagons to standard gauge using 660 purpose-built bogies manufactured at workshops, supporting flows in remote areas. The yard integrated with local workshops for conversions, including six 830-class diesel-electrics, emphasizing manual pit-based methods for robust mineral wagons. Today, bogie exchange is limited to select industrial applications, with historical reliance on manual pits evident in past iron ore operations at sites like . The Peterborough facility has been largely supplanted by techniques. Overall demand declined post-1970s due to progressive , including the 1970 east-west link completion and subsequent broad-to-standard conversions, reducing break-of-gauge points and favoring through-running on unified tracks.

Belarus

Bogie exchange in Belarus is primarily employed at the border with to facilitate the transition between the 1520 mm broad gauge used domestically and the 1435 mm standard gauge in the , enabling seamless connectivity for both freight and passenger services along key international routes. This method addresses the persistent gauge incompatibility inherited from the Soviet era, allowing trains to continue operations without full reloading or of cargo and passengers. Facilities are concentrated at Brest-Tsentralny railway station, where specialized infrastructure supports the lifting and swapping of bogies to accommodate cross-border traffic on lines linking Belarus to Polish networks and beyond. The process at involves hydraulic lifts to elevate rail vehicles, followed by the removal of 1520 mm bogies and installation of 1435 mm equivalents from reserve stocks, with operations conducted in a covered to protect against . This applies to both freight wagons carrying such as containers and bulk commodities and passenger coaches on international night trains, where travelers remain aboard during the exchange to minimize inconvenience. Traditional bogie exchange typically requires over one hour per train, contributing to overall border delays of at least two hours for freight movements, though this supports substantial volumes integral to regional trade flows. For electric locomotives, which dominate Belarusian rail operations, procedures include isolating the to disconnect from the overhead , ensuring safety during the swap and preventing electrical hazards across differing systems at the border. This step is critical for services like those hauled by Belarusian electric models adapted for international runs, maintaining compatibility with both and systems prevalent in the region. Post-exchange, locomotives may be reattached or substituted to match the new and power standards on the Polish side. Historically, bogie exchange at has played a vital role in preserving rail following the Soviet Union's in 1991, when retained the 1520 mm gauge while neighboring states standardized on 1435 mm, necessitating continued investment in border facilities to sustain economic ties with . This infrastructure evolved from manual processes in the early post-Soviet period to more streamlined operations by the early , underscoring 's commitment to managing gauge barriers amid geopolitical shifts. In contemporary operations, bogie exchange supports Belarus's integration into broader Eurasian rail corridors, such as the , by handling transcontinental freight and passenger flows that connect to via Brest as a key node. Recent enhancements, including faster transfer facilities at the , aim to reduce exchange times below 20 minutes through complementary technologies, though traditional bogie methods remain central for non-compatible , enhancing overall corridor efficiency and trade volumes.

Bolivia

Bolivia's railway network, primarily operating on 1,000 mm meter gauge across its Andean systems, interfaces with Peru's 1,435 mm standard gauge lines at the western border, necessitating gauge conversion methods such as exchange to facilitate cross-border freight movement. The key connection runs via the Guaqui-La Paz line, terminating at Guaqui on , where proposed facilities for wagon bogie changes at Guaqui or Desaguadero were suggested in the late to enable the transfer of commodities to Peru's Puno-Matarani railroad for export to Pacific ports. Although the border with via the Santa Cruz-Corumbá line operates on compatible meter gauge, eliminating the need for bogie exchange there, the Peruvian interface remains critical for Bolivia's mineral exports, with limited direct rail continuity often supplemented by lake ferries. Bogie exchange practices in center on proposed operations for border transfers. These exchanges primarily support the transport of minerals such as tin and other metals from Andean mines, with passenger use of bogie exchange rare, as cross-border travel typically relies on ferries across rather than through rail services, reflecting the network's freight-oriented design. Historically, bogie exchange was proposed in the to bolster tin exports, aligning with the expansion of the Andean System railways built between 1900 and 1920 to serve the Altiplano's mining industry, though modernization has been limited, preserving many manual processes. Operations face significant challenges in Bolivia's high-altitude Andean terrain, where elevations exceed 4,000 meters on the , imposing steep grades, sharp curves, and environmental stresses that affect hydraulic systems in , often requiring reinforced designs to maintain reliability during bogie exchanges. Poor conditions and inadequate further elevate costs and limit speeds, complicating freight handling at sites like proposed plants at Guaqui or Desaguadero. The practice is declining amid intense competition, with freight volumes dropping notably since the (averaging around 165,000 tons per line annually as of ), yet it remains vital for cross-border shipments essential to Bolivia's . Ongoing efforts, such as the 433 km upgraded by , highlight persistent needs, though passenger services have reached historic lows.

Canada

Bogie exchange is rarely employed in Canadian rail operations due to the country's predominant use of the standard 1435 mm gauge, which aligns with that of the and eliminates the need for gauge changes at border crossings like Windsor-Detroit for transcontinental freight traffic. This shared gauge facilitates seamless and USMCA trade, with container trains typically handled through intermodal lifting at key yards rather than bogie modifications. Historically, narrow-gauge lines existed in regions such as Newfoundland and parts of during the early , but gauge transitions were generally achieved through track relaying and equipment conversions rather than bogie exchange; for instance, the Grand Trunk Railway completed a major conversion from 5 ft 6 in broad to standard across 421 miles in 1873 by adjusting rails and modifying . In , early 20th-century rail activities occasionally involved adaptations for imported European equipment, though bogie exchange was not a primary method. Mechanized facilities for bogie-related maintenance exist at major yards like Toronto's and operations, but these focus on servicing and wheelset replacements rather than gauge-specific exchanges. Today, bogie exchange is largely obsolete in mainline service, supplanted by standardized equipment and lifting for any cross-border or intermodal needs, with limited occasional application on tourist heritage lines like the , which maintains its 914 mm narrow independently.

China

China utilizes bogie exchange at strategic facilities to enable seamless connectivity across gauge differences in its extensive network, primarily converting from the 1435 gauge to the 1520 broad gauge used by neighboring countries. This method supports both passenger and freight operations, addressing the challenges of international rail traffic without requiring full track conversions. The station, located on the China-Mongolia border in Autonomous Region, serves as a major hub for exchanges on the . Here, international passenger trains, such as the Beijing-Ulaanbaatar service (K23/K24), undergo replacement at a dedicated intermodal maintenance workshop, where carriages are hoisted and fitted with new bogies to match the Mongolian . This also applies to freight trains, ensuring continuity for cross-border commerce. Additionally, specialized vehicle transport trains at Erenhot employ removable and coupler systems, which eliminate the need for unloading and reloading , thereby shortening border crossing times from several days to under one day. At , on the China-Russia border, bogie exchange facilities handle conversions for rail traffic connecting to the , accommodating the influx of China-Europe freight trains that pass through this port. These operations involve large-scale yards for and bogie swaps, supporting over 60% of China-Russia overland trade volume. The station's infrastructure has been upgraded to manage increased cargo flows, including and timber, while maintaining compatibility with the differing gauges. Bogie exchange in traces its origins to the mid-20th century, coinciding with the development of rail lines aided by Soviet technical assistance, which established key connections despite gauge disparities. In the contemporary era, these practices integrate with the , enhancing Eurasian rail links through facility modernizations that boost efficiency and trade volumes, though integration remains constrained by persistent gauge limitations.

Finland

In Finland, bogie exchange is employed at the railway yard to facilitate cross-border rail traffic at the Tornio-Haparanda border with , converting between Finland's 1,524 mm broad and Sweden's 1,435 mm standard for both freight and services. The facility supports the handling of electric locomotives and wagons, aligning with the electrification of the Laurila-Tornio-Haparanda line, which enables seamless power continuity across the border despite the gauge difference. The setup at is small-scale and involves manual-assisted operations, where trains are lifted to allow removal and replacement, a process that is relatively slow and suited primarily to individual vehicle transfers rather than full train consists. A dedicated bogie exchange track was installed in the railway yard around 2023 to support this, complementing the existing dual-gauge Torne River Railway Bridge built in , which intertwines both gauges on a four-rail configuration. Operations have historical roots dating to the early , following Finland's independence from in 1917 and the subsequent opening of the cross-border rail link in 1919, when broad-gauge compatibility with was retained while enabling limited connectivity to . To minimize disruptions, exchanges are typically conducted during nighttime hours, particularly for night trains that have been a common feature of the route since its inception, allowing daytime schedules to proceed without interruption. Passenger services, which ceased in 1988, are set to resume with bogie exchange enabling direct connections, though freight remains the primary current use. Arctic conditions in northern present operational challenges for bogie exchange, including extreme cold that can affect mechanical processes and require specialized to prevent freezing of components during the lifting and swapping procedure. Despite these difficulties, the facility is maintained as a practical interim solution. 's integration into the and has prompted studies for alternative gauge solutions, such as constructing a 30 km standard-gauge extension from into to bypass exchanges entirely and enhance connectivity with and . However, the broad-gauge network, including the Tornio facility, continues to be preserved for ongoing links to , ensuring continuity for eastern freight corridors amid geopolitical shifts.

Germany

Germany's railway network operates on a unified standard of 1435 mm, a standardization achieved post-World War II through conversions of any residual broad lines inherited from earlier conflicts, ensuring seamless connectivity across the country and with most neighbors. Historically, in the mid-20th century, exchanges were employed at facilities near the Polish-Soviet border to accommodate freight traffic destined for the Soviet Union's 1520 mm network. Today, exchange is rarely used for gauge conversion in due to the prevalence of standard gauge infrastructure, but it remains integral to operations in modern workshops, such as those operated by DB Fahrzeuginstandhaltung GmbH, where complete bogie swaps occur during revisions, overhauls, and accident repairs to maintain fleet reliability on EU freight corridors. These facilities, including those in the region near like the Ausbesserungswerk , emphasize efficient diesel and servicing, incorporating non-destructive testing, component refurbishment, and assembly for heavy-duty freight applications. Recent developments prioritize variable gauge bogie technologies, such as Alstom's adjustable designs capable of seamless transitions from meter to standard gauge, reducing reliance on traditional exchanges for occasional international or specialized operations while retaining bogie swaps for comprehensive repairs.

Iran

Iran utilizes bogie exchange at border stations to address the gauge disparity between its standard 1435 mm rail network and the 1520 mm broad gauge employed by neighboring countries in Central Asia and the Caucasus, enabling seamless freight movement for regional trade routes connected to Armenia and beyond. Although the Razi station on the Iran-Turkey border operates with matching 1435 mm gauges and thus does not require bogie exchange, it serves as a critical gateway for Caucasus-oriented cargo, handling up to 120 wagons daily through coordinated exchanges with Turkish railways. This infrastructure supports the flow of goods trains toward 1520 mm networks further north, facilitating trade volumes aimed at one million tons annually between Iran and Turkey. Bogie exchange practices are implemented at key northern facilities such as and Inche Borun stations along the border, where dedicated infrastructure—including multiple standard and broad-gauge tracks, repair depots, and 24-hour operations—accommodates the process for freight wagons. These sites primarily manage oil, minerals, containers, and general goods trains destined for or originating from markets, with diesel locomotives dominating freight services due to the predominance of non-electrified lines in cross-border operations. The exchange at , for instance, boosts capacity to 400 wagons per day, reducing overall transit times from border to southern ports like to approximately 53 hours, though procedural and geopolitical delays often extend handling periods. For routes involving , which operates on 1520 mm gauge, bogie exchange would be essential upon completion of the planned direct Iran-Armenia rail link via the Norduz-Agharak border, currently in development to enhance connectivity without intermediate . The development of bogie exchange capabilities in traces back to the , coinciding with the completion of the strategic Turkey-Iran railway in 1970, which aimed to revive ancient trade pathways by integrating Iran's network with Eurasian routes. This era saw initial investments in border facilities to handle gauge conversions, supporting early freight links to Soviet-influenced territories. However, international sanctions imposed since the late have significantly hampered modernization, restricting access to technology, funding, and spare parts, thereby slowing expansions and increasing operational inefficiencies at exchange points. Under the International North-South Transport Corridor (INSTC), is prioritizing infrastructure upgrades, including enhanced bogie exchange at Astara (Iran-Azerbaijan border) and Inche Borun, to streamline cargo from and Caucasian origins to ports. These efforts, valued at projects like the $75 million modernization of Inche Borun by and the $2.2 billion Rasht-Astara line, seek to minimize break-of-gauge disruptions through improved facilities and potential dual-gauge extensions, despite persistent sanction-related delays in financing from partners like and .

Kazakhstan

Kazakhstan functions as a critical rail hub in , employing exchange primarily at its border with to address the gauge break between China's 1435 mm standard gauge and the 1520 mm broad gauge prevalent in Kazakhstan and connected Russian networks. Key sites include the Dostyk station on the Kazakh side, directly opposite Alashankou in , where exchanges occur alongside options for freight. While the shared 1520 mm gauge with eliminates the need for exchanges at those borders, occasional 1435 mm links support limited standard-gauge operations within Kazakhstan or for specific international connections. Bogie exchange practices in Kazakhstan emphasize large-scale handling of Belt and Road Initiative freight, with Dostyk equipped to process both passenger and freight wagons through dedicated exchange points supporting 10 bogie sizes for passengers and 42 for freight. Automation has been integrated into border operations, including electronic data exchange and customs processing, to streamline overall transit at facilities like Dostyk-Alashankou. In 2024, these efforts facilitated a record 32 million tons of rail cargo between and , with the Dostyk-Alashankou crossing managing approximately 18 million tons. The process accommodates electric and diesel locomotives hauling energy commodities, such as products derived from pipelines, enabling continued post-exchange for exports to . Facilities at Dostyk allow parallel bogie exchanges for extended trains of over 50 wagons, optimizing throughput for bulk goods like metals, grains, and hydrocarbons. Historically, the infrastructure originated from Soviet-era initiatives, with construction of the Alashankou-Dostyk line beginning in 1954, pausing amid Sino-Soviet tensions in the 1960s, and resuming in 1985 before completion in 1990. Freight operations commenced in 1991, followed by passengers in 1992, with modernizations in the 2000s enhancing capacity to bolster energy exports amid rising hydrocarbon trade volumes. Efficiency at Dostyk involves exchanges taking about 5 hours for a full , while freight combines exchanges with to minimize delays, supporting annual volumes exceeding 18 million tons and reinforcing Kazakhstan's Eurasian role. The lifting and incorporates elements for faster handling.

Moldova

In Moldova, bogie exchange is primarily employed at the Romanian border to facilitate rail connections between the country's 1520 mm broad gauge network and the 1435 mm standard gauge used in and the . This process enables limited cross-border freight and passenger services, particularly for exports and transit to EU markets, as Moldova's rail infrastructure remains a legacy of its Soviet-era integration. Historically, exchanges supported agricultural exports in the , when rail freight volumes peaked at around 22 million tons annually before declining sharply due to the Soviet Union's dissolution and economic disruptions. and other agricultural products were key commodities transported via rail to regional markets, with gauge changes at border facilities enabling onward movement to non-Soviet destinations. By the late , however, underinvestment and geopolitical shifts reduced reliance on such operations, as gained dominance for shorter-haul agricultural shipments. Facilities for bogie exchange are concentrated at border stations, notably Ungheni on the Moldova-Romania crossing and Giurgiulești near the , where wagons and carriages are manually lifted and bogies swapped to accommodate gauge differences. Chisinau marshalling yards primarily handle domestic sorting and loading of small freight volumes, such as building materials, but lack dedicated gauge-change equipment, relying instead on border operations for international traffic. These manual processes are suited to Moldova's modest rail freight scale, which averaged under 5 million tons annually in recent years, focusing on bulk goods like scrap metal imports and exports. As a post-Soviet holdover, 's exchange practices face ongoing challenges from political instability, including financial crises at the state railway company CFM, wage arrears leading to worker protests, and disruptions from regional conflicts like the issue. These factors exacerbate chronic underinvestment, with only €150 million allocated to rail infrastructure from 2007 to compared to €1 billion for roads, resulting in obsolete equipment and low operational efficiency. Currently, exchanges are rare, handling primarily the daily Chisinau-Bucharest and sporadic freight, with average border crossing times of 3.6 to 4.7 hours due to manual procedures and customs delays. In response, is pursuing gauge conversion, planning a 107 km electrified 1435 mm line from Chisinau to by 2030 to eliminate exchanges and integrate directly with networks.

North Korea

North Korea's railway system, predominantly standard at 1435 mm, requires bogie exchange operations at its with to accommodate the 1520 mm broad used there. This procedure occurs primarily at the Tumangang-Khasan crossing along the , facilitating limited passenger and freight services between the two countries. Due to the , trains cannot proceed directly, necessitating the replacement of bogies or wheelsets to transition across the . The bogie exchange process in is conducted manually under strict state control by the , reflecting the country's centralized and isolated rail operations. Workers lift the carriages using jacks and swap the bogies, a labor-intensive method that persists amid economic constraints and limited access to advanced technology. and , remnants of earlier eras, continue to support some border operations, particularly where is unreliable. The system's historical ties to Soviet influence are evident, though adopted standard gauge post-World War II, diverging from the Soviet broad gauge standard. These exchanges are infrequent, constrained by that restrict trade and technology transfers, resulting in sporadic rail traffic across the border. Maintenance challenges in North Korea's aging , exacerbated by sanctions and shortages, contribute to operational opacity, with limited available on procedures or timelines. The process typically extends transit times significantly, often exceeding one hour per train due to manual handling and equipment limitations. Despite these hurdles, the Tumangang-Khasan crossing remains essential for North Korea's imports, including , fuel, and materials vital to its economy, with recent increases in underscoring its strategic role. No reports indicate recent modernization of bogie exchange facilities, as ongoing sanctions continue to hinder upgrades.

Peru

Bogie exchange in Peru primarily facilitates freight operations across varying s in the country's coastal and Andean rail networks, particularly at the Bolivian border where standard (1435 mm) lines connect to narrow systems in regions. The Puno-Matarani railway, a key standard route reaching high altitudes over 4,000 meters in the , supports mineral exports but encounters incompatibility with Bolivia's meter (1000 mm) network across . To address this, proposals from the late 1970s suggested wagon bogie change facilities at the Desaguadero border crossing, enabling direct transfers for copper and other cargoes without full via . In mining areas, Peru's legacy 914 mm narrow lines, such as those in the central , require exchanges to interface with the standard national network for onward transport to ports or borders. Facilities at locations like emphasize manual operations for freight wagons, focusing on exports from Andean mines, with locomotives adapted for high-altitude conditions including reduced oxygen levels and steep gradients—adaptations mirroring those in neighboring . These exchanges typically involve lifting wagons to swap bogies, prioritizing durability for heavy mineral loads. Historically, Peruvian rail development in the early 1900s supported Andean trade, extending standard gauge lines to by 1908 to transport minerals toward coastal ports, though initial coastal railways from the 1850s aided broader export economies including . Usage peaked with mineral booms but declined mid-20th century due to competition from trucks, reducing rail's share of freight to sporadic levels. Today, exchanges remain infrequent, often taking 30-50 minutes per wagon in manual setups, but hold revival potential amid exploration in the region, where projects like Falchani could leverage border rail links for exports via proposed bioceanic corridors connecting to .

Romania

In Romania, bogie exchange operations are essential at the border to bridge the 1435 mm standard of the rail network and the 1520 mm broad of , supporting both passenger and freight traffic across integrated EU corridors. The primary facility is located at Dornești near the Vadul crossing, where dual-gauge tracks enable bogie changes for trains entering or exiting ; additional sites include Halmeu (for the Diakove crossing) and (for train ferries from Illichivsk). These exchanges allow seamless continuation of services, such as the restored Galați-Reni line under EU initiatives. Practices at these borders typically involve semi-automated processes using hydraulic lifts to swap bogies on passenger cars, minimizing downtime compared to full manual methods, while freight often combines bogie exchange with at terminals like the Grampet facility in Dornești to handle high volumes efficiently. Romania's electrified rail infrastructure on key corridors, such as the Rhine-Danube line, ensures electric traction for post-exchange operations, enhancing connectivity to . Historically, bogie exchange emerged post-World War II to sustain rail links with Soviet-era networks in , evolving into modernized systems to bolster trade, including Ukrainian grain exports routed through port via solidarity lanes. Currently, reliance on bogie exchange is diminishing amid EU-Ukraine talks to extend 1435 mm westward into by 2027, potentially eliminating the need at borders like Dornești and Halmeu. Nonetheless, these facilities remain vital for EU-Ukraine Solidarity Lanes, enabling the flow of , essential goods, and support for and military logistics amid regional tensions. Capacity constraints persist, with daily limits around 70 wagons at major crossings, underscoring the push for upgrades.

Russia

Russia's extensive 1520 mm network, managed by (RZD), necessitates bogie exchange operations primarily at international borders where gauges differ, particularly with standard-gauge (1435 mm) systems in neighboring countries. locations include the border crossing at Zabaikalsk with , where freight and passenger services transition to Chinese lines, as well as the Vainikkala-Buslovskaya crossing with and the Naushki-Sukhbaatar crossing with . At Zabaikalsk-Manzhouli, the facility features extensive bogie exchange and yards to handle the gauge break, supporting the Trans-Siberian Railway's eastern extension. For the Finland border, the minimal 4 mm gauge difference (1524 mm Finnish vs. 1520 mm ) allows direct operation without bogie exchange, using dual-electrification locomotives compatible with both 25 kV AC and 3 kV DC systems. Similarly, the border employs the same 1520 mm gauge, enabling seamless passage without gauge adjustment. In contrast, at Zabaikalsk, practices focus on automated bogie exchange for services like the Trans-Manchurian Express, where hydraulic lifts raise carriages to swap bogies, typically taking 2 to 6 hours. Freight operations on the Trans-Siberian primarily rely on between broad-gauge wagons and standard-gauge Chinese ones, though bogie exchange is applied to specialized cargo such as liquid bulk to avoid reloading. RZD employs a mix of diesel and electric locomotives, with completed to Zabaikalsk in 2021 to enhance efficiency on the Trans-Baikal line. The Zabaikalsk hub processes over 50 trains daily, accounting for nearly 60% of Russia-China rail cargo volume, with monthly throughput exceeding 1,600 trains as of 2023. These operations trace their roots to the Tsarist-era construction of the (1891–1916), but bogie exchange became essential after China converted the former Russian-built to standard gauge during the Japanese occupation (1931–1945) and retained it post-1952 nationalization. Facilities at border hubs like Zabaikalsk incorporate adaptations for Siberia's , including heated enclosures and insulated equipment to maintain functionality during temperatures as low as -50°C, preventing mechanical failures in bogie handling and . In modern developments, Russia's integration into the facilitates rapid internal gauge-compatible movements with minimal border delays, often under 15 minutes for customs clearance among member states. Bilateral agreements with have optimized Zabaikalsk operations, including a second rail line under construction to boost capacity. RZD is expanding the 1520 mm network to Arctic routes, such as the Northern Latitudal Railway, to support resource transport and integration with the , maintaining consistent gauge practices without additional exchanges.

Spain

In , bogie exchange serves as a key method for enabling rail transitions between the Iberian broad of 1,668 mm, which dominates the conventional network, and the 1,435 mm standard used on high-speed lines and for connections . This practice is particularly vital at the Franco-Spanish , such as the Hendaye-Irún crossing, where it supports seamless high-speed services and freight operations across boundaries. Historically, bogie exchanges have been employed since the for trains like the Sud Express, allowing wagons to be adapted without full vehicle . The technique gained prominence in the as part of efforts to integrate Spain's isolated rail system with European networks, with early implementations at border facilities like and Irún to facilitate cross-Pyrenean travel. Advancements accelerated following the 1992 Barcelona Olympics, which spurred the construction of the Madrid-Seville high-speed line on standard gauge, creating new internal "borders" where bogie exchanges or equivalents were needed for . These exchanges typically involve jacking up vehicles and swapping complete s, a process requiring specialized pits and taking at least 10 minutes per for passenger coaches. In practice, bogie exchange in is often combined with axle systems, such as those developed by and , to minimize downtime on high-speed routes. At border stations like Irún, electric locomotives are routinely swapped due to differing standards—Spain's 3 kV DC on Iberian gauge lines versus France's 1.5 kV DC or 25 kV AC—further streamlining the overall transition. AVE trainsets, including series 130 (Talgo-based), utilize hybrid approaches where bogie exchange supplements variable axles, enabling run-through times of 10-20 minutes while maintaining speeds up to 30 km/h during the process. Currently, traditional pure bogie exchanges are being phased out in favor of advanced Talgo variable gauge technologies, which allow axles to adjust automatically without full bogie swaps, as seen in operations on lines like Madrid-Barcelona and Madrid-Málaga. By 2010, over 33 such facilities had been installed across the network, though five were later decommissioned, reflecting a shift toward self-propelled variable-gauge trains for greater efficiency in high-speed and freight corridors. This evolution supports daily volumes of around 36 trains at key changer sites, enhancing Spain's connectivity within the EU rail framework.

Tunisia

Tunisia's railway network operates a dual-gauge system inherited from its colonial era, with approximately 471 km of standard (1,435 mm) track concentrated in the northern region around and 1,674 km of meter (1,000 mm) track extending southward, where it dominates freight operations including transport from the mining basin. This configuration, established during rule to serve urban and export needs on standard while using narrower tracks for resource extraction in remote areas, limits and renders bogie exchange operations rare overall. The Société Nationale des Chemins de Fer Tunisiens (SNCFT) manages both systems, primarily employing diesel locomotives adapted for meter bogies in southern freight services. At the Algerian border near Ghardimaou, the rail connection utilizes standard gauge, enabling direct cross-border passenger and limited freight services without bogie exchange, as Algeria's linking lines also employ 1,435 mm track. Phosphate freight, a cornerstone of Tunisia's rail activity, occurs almost exclusively on dedicated meter gauge lines from mines to coastal ports like Sfax, where manual transloading rather than bogie exchange handles any necessary transfers to standard gauge or road/sea modes; facilities for such operations remain limited and infrequently used. Harsh desert conditions in the phosphate-rich south exacerbate maintenance challenges for rail infrastructure, including hydraulic components in locomotives and any potential exchange equipment, though documented bogie exchanges are scarce. Today, sees minimal application in , overshadowed by the expansion of road transport for bulk goods and the focus on modernizing meter gauge lines with investments exceeding $55 million for renewal. Occasional needs arise for Mediterranean export links, where wagons may interface with standard gauge port sidings, but these are handled through alternative methods rather than routine bogie swaps.

Ukraine

Bogie exchange operations in primarily occur at key border crossings to facilitate transitions between the country's 1,520 mm broad and the 1,435 mm standard used in the , enabling access to EU networks for freight and services. Major sites include the Chop station on the Hungarian and Slovak borders, where dual- tracks support exchanges, and the Halmeu-Diakove crossing on the Romanian border, which features dedicated facilities for changes. These locations handle critical cargo flows, including grain exports and , with Ukraine's operator Ukrzaliznytsia (UZ) maintaining bogie exchange workshops equipped with reserves of both types. Inherited from the Soviet era, these practices supported regional trade, including rail connections to ports for agricultural exports, though international gauge changes were essential for onward routes. Post-2022 , bogie exchange activities intensified to sustain wartime logistics, with rail becoming vital for transporting military supplies, (up to 100 wagons daily), and disrupted grain exports amid port blockades. Operations at major yards, such as Chop, employ semi-automated lifting systems for wagons, typically powered by electric or diesel locomotives for freight like , though the process can take several hours per due to disruptions and limits (e.g., up to 467 wagons daily across western borders). In response to EU integration aspirations, has modernized its border infrastructure, including the installation of bogie exchange lifts at the Romanian border in 2024, supplied by USAID to boost efficiency and handle an additional 24 units daily. These enhancements, part of broader TEN-T corridor extensions, aim to reduce delays and support non-stop freight movement, underscoring rail's role as a lifeline for wartime exports and connectivity.

United States

In the 19th century, American railroads employed a variety of track gauges, including 4 ft 8+1⁄2 in (1,435 mm) in northern networks, 5 ft (1,524 mm) in southern lines, and narrower gauges like 3 ft (914 mm) in mountainous areas such as . These inconsistencies created frequent breaks of gauge, disrupting freight and passenger traffic and necessitating workarounds like transshipment of or bogie exchange. Bogie exchange entailed using steam-powered hoists to lift the car body and replace its bogies with ones suited to the adjacent , a method that demanded substantial labor, dedicated storage for spare bogies, and specialized facilities but often produced unstable vehicles due to mismatched components. Efforts to resolve the "gauge muddle" accelerated in the late 1800s, driven by economic pressures for seamless interstate commerce. A pivotal event was the Great Gauge Change of May 31–June 1, 1886, when railroads across the American South coordinated the conversion of roughly 11,500 miles (18,500 km) of 5 ft track to 4 ft 9 in (1,448 mm), closely aligning with the northern standard. This massive, synchronized operation—accomplished over a single weekend with thousands of workers adjusting rails, ties, and —marked one of the largest engineering endeavors in railroad history and drastically reduced the need for bogie exchange by fostering a near-uniform national . By the early 20th century, full standardization to 4 ft 8+1⁄2 in had been achieved across the contiguous United States, rendering bogie exchange obsolete for mainline freight and passenger services. Today, with standard gauge dominating the network, the practice persists only rarely in workshop settings for maintenance or occasional conversions on isolated heritage lines, such as Colorado's preserved 3 ft narrow-gauge tourist operations. No routine bogie exchanges occur at international borders, as the United States shares standard gauge with Mexico on main lines despite some historical regional variations in Mexico.

References

  1. [1]
    [PDF] Study of Port Pirie Bogie Exchange
    Bogie exchange is the most important of the current methods of load transfer at break of gauge locations on Australia's railway network. In principle, the ...
  2. [2]
    [PDF] The “Evil” of Railway Gauge Breaks: A Study of Causes in Britain ...
    Feb 25, 2022 · By the 1870s, several adapter technologies had developed to reduce these costs, the most common of which was bogie exchange, whereby each rail ...
  3. [3]
    [PDF] Efficient Cross-Border Transport Models - ESCAP
    Bogie change and variable gauge may be more useful for light trains. Transshipment has been found more practical for cross-country rail operations in absence.
  4. [4]
    Effectiveness Evaluation of the Bogie Exchange and the Automatic ...
    Aug 6, 2025 · The variable gauge railway consists of the bogie system to change the length of the wheel shaft and the gauge changing railroad track. Thus, it ...
  5. [5]
    Untangling track gauges: not all railway tracks are the same
    Each wagon is raised by a massive wagon jack, the bogies underneath are exchanged and the train continues its travel on another gauge.
  6. [6]
    Bogie Exchange Systems - Andrew Engineering
    The Andrew Engineering Bogie Exchange System offers a Superior Solution to these traditional systems by removing the need for deep pits and confined spaces.
  7. [7]
    [PDF] NBER WORKING PAPER SERIES COLLUSIVE INVESTMENTS IN ...
    By the 1870s, several adapter technologies had developed to reduce these costs, the most common of which was bogie exchange, whereby each rail car was raised ...
  8. [8]
    https://mediarail.wordpress.com/europe-and-its-russian-gauge-tracks/
  9. [9]
    https://bordercrossinghub.com/erenhot-zamin-uud-border-crossing/
  10. [10]
    Europe and its Russian gauge tracks - Mediarail.be - WordPress.com
    Jun 30, 2022 · These workshops have tracks with both 1,520mm and 1,435mm gauges. The cars are lifted one by one and their bogies are exchanged. These workshops ...
  11. [11]
    Erenhot & Zamin Uud Border Crossing
    The line was built in the 1950s as a major project of socialist cooperation between the Soviet Union, Mongolia, and the People's Republic of China. It was a ...
  12. [12]
    Bogie and wheelset changing technology
    Our bogie and wheelset changers enable the rapid exchange of complete bogies or individual wheelsets, both in workshops with floor-level and elevated track ...
  13. [13]
    In-Floor Lifting Plant for Underground Railway Rolling Stock
    Jun 12, 2018 · During bogie exchange, the mobile body supports are positioned beneath the vehicle- specific lift support points so that the rail bridges can be ...
  14. [14]
    [PDF] Safety Rules - Union Pacific
    May 10, 2022 · Wheels must be chocked to prevent equipment movement, except where one-spot in-floor jacks are being used. Do not go under or place any part ...Missing: bogie | Show results with:bogie
  15. [15]
    Lifting Jacks LJ | CMCO
    Various lifting jack systems in load classes from 5 t to 50 t. Designs as permanently installed, with hall floor trolley or on rail trolley. Request a Quote ...<|control11|><|separator|>
  16. [16]
    Railway Car Hoist Systems for Efficient Maintenance
    Aug 1, 2024 · One key safety feature is the self-locking action used in the lifting mechanism, designed to lock in place and prevent accidental lowering of ...
  17. [17]
    Nencki - Railway Technology
    Bogie exchange and lifting systems are used in replacing single bogies that may have failed tests, elevated up to 1.7m-high. Click the link in the company ...
  18. [18]
    [PDF] How much capacity is needed? - Toolwell
    And if you are going to lift-up all 4 corners at the same time, each jack must carry 5 tons. So use four 5-ton jacks to carry the total weight of 20 tons. 10.
  19. [19]
    Bogie-Axle Exchange Systems | CMCO
    Bogie-Axle Exchange Systems. Can be customised or expanded. For the purpose of exchanging bogies and for maintenance work on vehicles, Pfaff-silberblau ...
  20. [20]
    A Soviet Spoke in the Wheels of Progress - Nick Selby
    Jun 16, 1994 · For trains from Europe, the European-gauge bogies were removed and rolled out from underneath the cars, and then Soviet-gauge bogies rolled in ...
  21. [21]
    (PDF) Safety and Risk Management: Hydraulic system failures and ...
    Sep 27, 2024 · Cylinder Issues: Damage to hydraulic cylinders can cause loss of force or control, affecting drilling operations. Valve Failures: Sticking o ...
  22. [22]
    [PDF] Hydraulic Synchronous Lifting System - Presentation Title
    A hydraulic synchronous lifting system uses a PLC controller, feedback sensors, and controlled valves for even, precise lifting, reducing manual error.
  23. [23]
    Device for aligning and forming bogie and forming process based ...
    The invention discloses a device for aligning and falling a bogie and a falling process based on the device, comprising a frame main body, a positioning ...
  24. [24]
    None
    ### Summary of Bogie Lowering Procedures During IOH
  25. [25]
    [PDF] Railways in Colonial India: An Economic Achievement?
    By 1900, the metre gauge lines comprised 41% of the network compared to 56% on the Indian standard gauge. In yet another break of gauge, many of the small ...
  26. [26]
    [PDF] CIRCULAR NO. M-3 Steam Locomotive Inspection, Maintenance ...
    locomotive owner and/or operator shall not return the steam locomotive boiler or appurtenances to service unless they are in good condition and safe and ...
  27. [27]
    Paper No. 472 - SteamIndex
    On bogies and pony trucks did the LMS still put a thicker tyre on the bogie than on the coupled wheels? The Author in reply to Mr. Windle: In his opening ...
  28. [28]
    Train Maintenance | PRC Rail Consulting Ltd
    A quicker method is to use two cranes together which lift both ends of the car body together and free both bogies at the same time. The body can then be removed ...
  29. [29]
    FLEXX Power bogies for locomotives: Challenges and developments
    Dec 3, 2014 · FLEXX Power bogies for locomotives: Challenges and developments ; High traction and braking forces; Low product price and short delivery time ...
  30. [30]
    When Do I Need to Reset the ECU? - ADAS Calibration
    Aug 29, 2023 · ECU reset refers to the process of clearing or resetting the learned adaptive values and settings in the engine control unit.<|control11|><|separator|>
  31. [31]
    https://www.cmco.com/en-us/products/rail-technology/rail-technology/bogie-axle-exchange-systems/bogie-axle-exchange-systems-baes/
  32. [32]
    https://www.cmco.com/en-gb/products/rail-technology/verkehrstechnik/bogie-axle-exchange-systems/
  33. [33]
    [PDF] Chapter 4 - Operational Requirements - ESCAP
    Federation, Turkmenistan and Uzbekistan; and the 1,435 mm gauge as well as 1,676 mm ... Bogie changing is an inter-gauge transfer technique by which each wagon ...
  34. [34]
    Pfaff-silberblau - Lifting jack system - Columbus McKinnon
    The 16 Pfaff-silberblau lifting jacks each have a load capacity of 25 tonnes and can lift and lower entire multiple units with a total weight of up to 400 ...Missing: locomotive | Show results with:locomotive
  35. [35]
    Bogie Axle Exchange Systems BAES | CMCO
    For the purpose of exchanging bogies and for maintenance work on vehicles, Pfaff-silberblau offers a range of bogie exchange systems with various possible ...Missing: diesel adaptations
  36. [36]
    Bogie-Axle Exchange Systems - Columbus McKinnon
    Bogie-axle exchange systems are for exchanging bogies and maintenance, with scissor or spindle lift options, and integrated into track or foundation.Missing: alignment laser guided
  37. [37]
    [PDF] Automatic track gauge changeover for trains in Spain - Vía Libre
    Aug 31, 2010 · Specifically, Spanish automatic gauge changeover systems allow trains to pass automatically from a line with an Iberian track gauge to another ...
  38. [38]
    Variable gauge axle systems - Railway Supply
    Apr 15, 2021 · The practical application of variable gauge axles began in 1969, when the first Talgo RD passenger train arrived from Barcelona to Geneva. Talgo ...
  39. [39]
    Variable gauge systems, a smart solution for increasing the ...
    Oct 20, 2011 · The development of variable gauge bogies is presented as an alternative to transshipment and bogie changing methods. The cross-border ...Missing: exchange | Show results with:exchange<|separator|>
  40. [40]
    new technologies of gauge variation for wheelset vehicles crossing
    Aug 6, 2025 · There are two possible solutions, namely the exchange of axles (rolling element that steering bogies) or adapt them to the new gauge on the fly ...
  41. [41]
    Simmons DCP-400/600 Dual End Combination Wheel Press
    The press is available as a 600 ton pressing force model or a derated 400 ton system for customers with lower capacity requirements. Simmons Wheel Press ...
  42. [42]
    https://portal.engineersaustralia.org.au/system/files/engineering-heritage-australia/nomination-title/HRP.Steamtown%2520Peterbrouugh.Nomination%2520and%2520report.V2.15%2520Nov%25202017.pdf
  43. [43]
    Landy - German translation - Linguee
    Railways have contracted Windhoff Bahn- und Anlagentechnik GmbH from Rheine, Germany, for the delivery of two wheelset exchange and wheelset transfer ...
  44. [44]
    Study of Port Pirie Bogie Exchange
    Feb 2, 1977 · Bogie exchange facilities have been established at several locations including two in South Australia, at Port Pirie and Peterborough.Missing: history | Show results with:history
  45. [45]
    [PDF] STEAMTOWN HERITAGE RAIL CENTRE PETERBOROUGH
    Aug 13, 2017 · With Peterborough replacing Terowie as the break-of-gauge station, a Bogie Exchange Depot was established at Peterborough. One of its first ...
  46. [46]
    https://www.britannica.com/place/Bolivia/Transportation
  47. [47]
    [PDF] Greener Transport Connectivity for Eastern Partnership Countries
    gauge requires goods and passengers to change trains, or use a bogie exchange. This adds at least 2 hours of travel time for freight, but it can be much more.
  48. [48]
    [PDF] BOLIVIA NATIdNAL TRANSPORT STUDY - World Bank Documents
    Pacific Ocean, linking the meter gauge Viacha-Guaqui railroad in Bolivia with the standard gauge Puno-Matarani railroad in ... is a wagon bogie change plant ...
  49. [49]
    https://www.cn.ca/en/our-services/maps-and-network/intermodal-terminals/
  50. [50]
    News Bolivia - Friends of Latin American Railways
    A very recent report from February 2024 shows that passenger traffic is currently at its lowest level in Bolivian railway history.
  51. [51]
    Railway Gauges in Ontario - Charles Cooper's Railway Pages
    The US railroads bordering on southwestern Ontario had already adopted the 4ft 8½in Standard Gauge (with the notable exception of the Erie Railroad with a 6ft ...
  52. [52]
    Intermodal Terminals | Our Network | Our Business | cn.ca
    CN's intermodal terminals allow shipping via rail, trucks, and vessels, with a rail network touching three coasts in North America.
  53. [53]
    Significant Dates in Canadian railway history.
    1873, October 3-4 - The Grand Trunk Railway converts the gauge of its line between Stratford and Montreal, 421 miles together with 60 miles of sidings, from 5' ...<|control11|><|separator|>
  54. [54]
    Quebec Railways Historical Research Institute / Data Bases
    The object of the Institute is to favour the research and publication of works on the history of Quebec railways, and of related subjects in transportation ...
  55. [55]
    Equipment Specifications | Safety Guidelines & Regulations - CN Rail
    To find the equipment that's right for you, select the product you want to ship and we will tell you the rail car or container you can use.Missing: bogie | Show results with:bogie
  56. [56]
    Scenic Train Rides in Canada: Adventure Routes - VIA Rail
    Discover all the richness of Canada's wilderness in a one-of-a-kind train ride. These scenic routes will carry you away, for a journey you won't forget.
  57. [57]
    Russia-China Land Infrastructure: Changes to Cross-Border Road ...
    May 27, 2025 · Rail gauge interoperability. China uses a 1435 mm standard gauge, whereas Russia uses a 1520 mm broad gauge. On the Chinese side of the Sino- ...
  58. [58]
    Mongolia and China agree plan to connect rail networks
    Feb 21, 2025 · A “bogie exchange” at Erenhot station on the Chinese border. The new line will be dual tracked to avoid the need for this process ...
  59. [59]
    Cross-border passenger trains shift bogies in Erenhot - China Daily
    Jun 15, 2018 · Erenhot intermodal maintenance workshop overhauls international passenger trains and redirects bogies.<|separator|>
  60. [60]
    Train specialized for transporting vehicles used to shorten border ...
    Apr 13, 2020 · A border-crossing train loaded with vehicles enters the wheel replacement workshop at the Erenhot Port in north China's Inner Mongolia ...
  61. [61]
    Ulan-Bator - Beijing Train - Go Russia
    Due to the difference in a railway gauge between Mongolia and China, bogie exchange is necessary to enable cars to run through. Russia and Mongolia use a ...
  62. [62]
    Thriving border trade in Manzhouli benefits locals - People's Daily
    Sep 15, 2025 · The Manzhouli railway port, China's largest land port, handles more than 60 percent of China-Russia overland trade. The port has developed ...
  63. [63]
    Key Challenges and Countermeasures with Railway Accessibility ...
    (2) Bogie change operations significantly prolong the arrival time. Bogie change operations require changing the steering bogie (including the wheelset) ...
  64. [64]
    Passenger rail between Finland and Sweden could start in late 2025
    Jan 27, 2025 · Passenger train traffic from Finland via Tornio to Haparanda would open up the possibility of traveling to Sweden and the rest of Europe by land.
  65. [65]
    Construction at the border requires close cooperation in the ...
    May 23, 2024 · The project involves international cooperation, electrifying tracks across the border, and requires close cooperation due to different rail ...Missing: bogie exchange history
  66. [66]
    Report shows that changing the track gauge would not be cost ...
    Apr 12, 2023 · The first one is a process already used in Tornio, which involves lifting the train to change the bogies. The process is quite slow and is ...Missing: exchange challenges
  67. [67]
    The Rail Connection Between Sweden And Finland
    Dec 13, 2024 · In 1919 the bridge with both gauges, standard (4' 8 !/2") and 1524 mm (5'), intertwined in a four rail track, was opened, short after Finland ...
  68. [68]
    Ripping Up the Rails of Empire: Baltic and Finnish Railways Turn ...
    The Baltic and Finnish rail networks are shifting to European standard gauge for NATO troop movement, to sever ties with Russia, and to improve security and ...
  69. [69]
    Break of gauge - Wikipedia
    A train on 1435 mm standard-gauge track leaving Russia. It is bound for Manzhouli, China, having replaced its 1520 mm-gauge bogies with standard-gauge bogies ...
  70. [70]
    The History of Railway Traffic at the Finland-Sweden Border
    Passenger trains between Tornio and Haparanda ceased to run in 1988. The rail connection is now electrified, enabling the return of passenger train services.Missing: bogie exchange
  71. [71]
    [PDF] Better Integrating Finland's Rail Network - Theseus
    Sep 18, 2024 · Figure 4: Bogie exchange hydraulic lifts in the railyards of Chop, Ukraine. ... Railway Gazette, 2017. Helsinki – Tallinn tunnel feasibility ...<|control11|><|separator|>
  72. [72]
    Finland: Standard gauge rail links are on the agenda
    Oct 14, 2025 · The plans envisage that the first section of Rail Nordica would run for 30 km from Haparanda and Tornio to the key junction with Finland's north ...Missing: bogie exchange
  73. [73]
    Radsätze & Drehgestelle - DB Fahrzeuginstandhaltung GmbH
    Profitieren Sie von unserem Rundum-Service für Drehgestelle und Radsätze im Rahmen von Revisionen sowie der fachgerechten Sanierung von Unfallschäden aller Art.Missing: Austausch | Show results with:Austausch
  74. [74]
    Ausbesserungswerk Dessau - Wikipedia
    Der Arbeitsumfang enthält nach der Demontage die Instandhaltung und Prüfung von Drehgestellanbauteilen und Schraubenfedern, des Drehgestellrahmens, der ...
  75. [75]
    Alstom: Team aus der Schweiz und Deutschland für umspurfähiges ...
    Jan 23, 2020 · Das neu entwickelte Drehgestell kann seine Spurweite von Meter- bis Normalspur (1.435 mm) stufenlos einstellen und löst damit die ...Missing: Drehgestellaustausch | Show results with:Drehgestellaustausch
  76. [76]
    [PDF] Corridors: A Tool to Boost International Freight
    Oct 14, 2020 · Cargo transport between the two counties up to one million ton annually. Iran-Turkey Rail Border- Razi Station ... • Lengthy bogie exchange time ...Missing: diesel | Show results with:diesel
  77. [77]
    [PDF] Railways of Iran (RAI) International Affairs By - ESCAP
    Feb 8, 2018 · ➢ Construction of the Bogie exchange site at Inche- Borun Station ... refrigerator wagons through this route. Page 29. Iran-Turkey Rail Border.
  78. [78]
    Iran-Azerbaijan-Armenia Railway Poised to Become Key Transit ...
    Aug 19, 2025 · She noted that Iran already has a railway up to Jolfa, and it has been confirmed that the line will be extended from Nakhchivan to Yerevan, The ...
  79. [79]
    Iran - trains-worldexpresses.com
    The strategic railway Turkey - Iran was completed in 1970 - Iran was completed. In 1971 passenger services Istanbul - Tehran started, initially with change ...Missing: bogie exchange history
  80. [80]
    [PDF] International North–South Transport Corridor: Investments and Soft ...
    May 11, 2022 · to the Iranian port of Bandar Abbas, with transshipment of containers or bogie exchange at the Astara station. • The Eastern Railway Route ...
  81. [81]
    [PDF] Central Asia's Rail Network and the Eurasian Land Bridge
    There have been trade routes between. Asia and Europe since the dawn of human history, culminating in the famous Silk. Road that ran a magnificent 15,000 km.
  82. [82]
    Report: China and Central Asia Railway Connections
    Oct 9, 2025 · This requires bogie changes or cargo reloading at border stations, which can take 24-36 hours depending on volume. Facilities at these points ...
  83. [83]
    Dostyk (Friendship)
    Existing wagon exchanging point has 10 sizes of bogies exchanging for passenger wagons and 42 sizes of bogies exchanging for freight wagons. Dostyk Station.Missing: efficiency | Show results with:efficiency
  84. [84]
    [PDF] STUDY ON BORDER CROSSING PRACTICES IN INTERNATIONAL ...
    The study extensively benefited from the visits made by the ESCAP study team to several border crossings (in chronological order): Sukhbaatar (Mongolia), Dong ...<|control11|><|separator|>
  85. [85]
    KTZ tests flexitank transport for oil exports to China - Railway PRO
    Sep 3, 2025 · Kazakhstan Railways (KTZ) has completed its first shipment of sunflower oil using flexitanks in 40-foot containers.
  86. [86]
    KTZ Launches New Innovative Format for Vegetable Oil Shipments ...
    Sep 3, 2025 · ALMATY – Kazakhstan Temir Zholy (KTZ) has introduced a new format for transporting vegetable oil to China, carrying out its first shipment ...
  87. [87]
    Sino-Kazakh Ties on a Roll - The Jamestown Foundation
    Jan 18, 2013 · Until now, the only railroad border crossing between China and Kazakhstan was between Alashankow in China and Dostyk station in Kazakhstan. This ...Missing: bogie | Show results with:bogie
  88. [88]
    [PDF] Tracks from the Past, Connectivity for the Future
    Moldova's foreign trade. Moldova's major exports, as measured in value, are manufactured goods. Most of these are shipped by road. However, most of the ...
  89. [89]
    Standard gauge railway 'backbone' proposed for Ukraine and Moldova
    Aug 1, 2023 · Map of the 1 435 mm gauge 'backbone' proposed to integrate the rail networks in Ukraine and Moldova with those in the European Union.<|control11|><|separator|>
  90. [90]
    Ultimate Train Travel Guide for Moldova - Paliparan
    Feb 24, 2024 · This Moldova train guide shows you an overview of all domestic Moldovan trains, international rail connections and general travel tips.<|control11|><|separator|>
  91. [91]
    Moldovan Railways announced its investment projects - Railway PRO
    Oct 18, 2023 · For transshipment activities between 1435mm and 1520 mm rail gauge tracks, the company uses 280 bogies and needs 200 additional bogies.Missing: exchange | Show results with:exchange
  92. [92]
    Political Liability. The Moldovan Railway's "Clinical Death" and Its ...
    Mar 16, 2021 · The disaster with salaries to employees paying and the protests of the railway workers highlighted the colossal problems of the railway industry ...
  93. [93]
    Moldova plans an electrified standard gauge railway to the EU
    Sep 25, 2025 · Moldova is planning to build a new railway to Romania, which would connect the country to the EU's rail network. The country is betting that ...
  94. [94]
    Moldova to build first electrified railway with European gauge on ...
    Sep 24, 2025 · Moldova to build first electrified railway with European gauge on Chisinau–Ungheni segment. Moldova is taking a historic step in modernizing its ...
  95. [95]
    Spotlight: North Korea-Russia Transport Infrastructure
    Sep 14, 2022 · North Korea uses the international standard 1,435-mm track gauge (distance between rails), but Russia uses a 1,520-mm gauge. This means Russian ...Missing: bogie | Show results with:bogie
  96. [96]
    North Korea - Railroads - GlobalSecurity.org
    Nov 14, 2024 · North Korean data show that the cost of rail transport is only 34 percent and 53 percent of road and maritime transport, respectively. In the ...
  97. [97]
    Making Solid Tracks: North Korea's Railway Connections with China ...
    Jan 7, 2019 · It is unclear, however, how much of the rail traffic at the Tumangang railyard is related to trade with Russia. Encompassing 1.2 square ...Missing: bogie | Show results with:bogie
  98. [98]
    The decline and fall of North Korea's once-great railways - NK News
    Apr 6, 2018 · The decline and fall of North Korea's once-great railways. Despite talk of major Russian investment, the future of the DPRK's trains is bleak.
  99. [99]
    N. Korea stresses repair of old railways amid push for expanded trade
    Feb 27, 2024 · North Korea's central government recently ordered North Pyongan Province to renovate and repair outdated sections of the province's railway network.
  100. [100]
    North Korea restores train service to Russia, boosting hopes for ...
    Jun 10, 2024 · After a four-year hiatus due to the coronavirus pandemic, passenger rail service between Russia and North Korea has been restored.
  101. [101]
    The New Russia-DPRK Economic Axis: Expansion of Tumangang ...
    Dec 18, 2024 · The Tumangang-Khasan railroad crossing was involved in the transfer of North Korean munitions to Russia.Missing: bogie gauge
  102. [102]
    Railway on top of the world - positive times for Peru's railways
    Oct 31, 2017 · By converting the line to 1,435mm gauge the Government hopes mining ... exchanging the 914mm gauge bogies for 1,435mm ones. □. □ In ...
  103. [103]
    American Lithium raises Peru project's investment by 22% to $847M
    Sep 25, 2025 · The updated investment includes plans to build a refinery at the project site in the Andean region of Puno.Missing: revival | Show results with:revival
  104. [104]
    A new mega railway across Latin America - Instituto Igarapé
    In Brazil and Bolivia, stretches of track are already in place but would have to be rehabilitated in order to accommodate much heavier traffic. In Peru, most of ...
  105. [105]
    Border Crossings: Romania - Ukraine - EGTRE
    Nov 19, 2024 · 1435 mm gauge traffic runs via the Ukrainian corridor line to Chop, with links to and from Čierna nad Tisou in Slovakia and Záhony in Hungary.
  106. [106]
    [PDF] for Strategy for the EU integration of the Ukrainian and Moldovan rail ...
    Jul 11, 2023 · (1435mm and 1520mm) and it will not require bogie exchange or new rolling stock with gauge adjustable wheelsets. The dual-gauge rail runs ...
  107. [107]
    USAID supplies bogie exchange lifts to improve the efficiency of rail ...
    Feb 23, 2024 · The USAID's Economic Resilience Activity (USAID ERA) has installed the first set of four bogie exchange lifts for Ukrzaliznytsia (UZ) at a railroad border ...Missing: Episcopia Buiandi
  108. [108]
    Romania's Grampet completes EUR 10 mln railway transhipment ...
    Apr 5, 2024 · ... located in Dorneşti (Suceava county), on the border with Ukraine. The facility, needed because of the different train gauges in Romania (and ...<|control11|><|separator|>
  109. [109]
    Ukraine Moves to Align Rail Gauge With Europe to Lviv by 2027
    Nov 2, 2025 · Ukraine plans to extend European-standard rail gauges to Lviv in western Ukraine by the end of 2027, allowing direct train travel to western ...
  110. [110]
    Solidarity Lanes: study on EU rail connections with Ukraine and ...
    Jul 11, 2023 · The study also assesses the way in which the new standard gauge lines in Ukraine and Moldova would work with the network elsewhere in these ...
  111. [111]
    Russia-China Land Infrastructure: Changes to Cross-Border Road ...
    May 27, 2025 · On the Chinese side of the Sino-Russian rail border crossing are large transshipment or bogie exchange facilities.Missing: Soviet era
  112. [112]
    [PDF] Security BIRC Working Group - UIC - International union of railways
    If a technology based on bogie exchange is used, the time required for cars to wait at border crossings will also be increased and bogies will need to be ...
  113. [113]
    Trans-Manchurian Railway Route: Map and Highlights
    The Trans-Manchurian Railway travels from Moscow to Beijing, with stops including Chita, Zabaikalsk, Manzhouli, Harbin, and Beijing.
  114. [114]
    RZD completes Zabaikalsk electrification | International Media
    Mar 24, 2021 · RUSSIA: Russian Railways has completed the 25 kV 50 Hz electrification of its 365 km line from a junction with the Trans-Siberian Railway at ...
  115. [115]
    Boosting Russia's “pivot to the South” and Trans-Eurasian connectivity
    The INSTC development would promote Eurasian intra- and transcontinental connectivity, reduce export costs, develop new production niches, and realize the ...
  116. [116]
    Russian Railways accelerates development of Zabaikalsk ...
    Aug 23, 2024 · To facilitate work on the narrow-gauge track, Russian Railways has purchased a special version of shunting diesel locomotives, while its ...
  117. [117]
    Russian Railways plans to increase container traffic to China
    Jan 27, 2023 · ... Zabaikalsk border crossings is over 1,600 trains per month, the top manager said. ... "We can send four trains per day more in average to these ...
  118. [118]
    Russian Railways note growth of cargo transportation via border ...
    Apr 20, 2023 · This week, a record was rgistered in Zabaikalsk: for the first time since 2014, 21 trains crossed the border over a day, says Russian Railways.
  119. [119]
    The Chinese Eastern Railway: geostrategic heritage from the turn of ...
    China ended this history by reclaiming the entire CER in 1952 (Liu and Li Citation2018). CER built by Russia was a Single-track railway with a track gauge of ...
  120. [120]
    Russia, China speed up construction of second railway line at ...
    May 22, 2024 · Russian Railways (RZD) and China Railways signed an agreement on comprehensive strategic cooperation on Thursday, RZD reported.Missing: exchange | Show results with:exchange
  121. [121]
    Border Crossings: France - Spain - EGTRE
    Oct 22, 2024 · Most freight trains change bogies at Hendaye. Contracts have been awarded to install mixed-gauge track between Irún and Astigarraga (south ...
  122. [122]
    Cambiador Ancho Dual - Adif
    The existing automatic gauge change systems in the national railway network allow trains to go from a line with Iberian gauge (1,668mm) to another with UIC ...
  123. [123]
    The variable gauge system for freight trains in Spain
    Jun 8, 2022 · The challenge of changing gauge for passengers is technically solved with technological developments carried out by Renfe, Adif, Talgo and CAF.
  124. [124]
    High speed gauge changer - WEB TRIA
    TRIA has constructed 33 gauge changers at the borders between the 1,668 mm gauge network and the 1,435 mm gauge network. Gauge changers are used daily by dozens ...
  125. [125]
    2.4 Tunisia Railway Assessment
    Due to historical reasons, the country has two different rail gauge systems. Thus SNCFT manages 471 km of standard 1,435 mm (4 ft 8 1⁄2 in) gauge network in the ...
  126. [126]
    Railroads of North Africa - UtahRails.net
    Tunisia's first railroads were built in 1874 during the last years of Turkish rule. They were standard gauge lines to serve the capital city of Tunis.
  127. [127]
    Tunisia-Algeria international service restored | RailUK Forums
    Aug 13, 2024 · Operating on a standard 1435 mm gauge, trains can reach a maximum speed of 130 km/h. ... The train's composition includes a locomotive, four ...
  128. [128]
    Phosphate railway modernisation loan signed | News
    Mar 4, 2024 · TUNISIA: The Saudi Fund for Development is providing a US$55m development loan to support the renewal of 190 km of railway in Sfax, ...Missing: bogie exchange
  129. [129]
    Railways resume phosphate transport from Om Larayes after eight ...
    May 28, 2025 · The Tunisian government aims to reach 230 wagons by early June 2025 and 340 by early July, for the transport of phosphates with the aim of ...
  130. [130]
    How Russia's war in Ukraine upended the breadbasket of Europe
    Apr 26, 2022 · Ukraine has bogie exchange systems at Chop, connecting to Hungary ... Bogie exchange process, rail and road network maps and port ...
  131. [131]
    Railroads in the Late 19th Century - Library of Congress
    The first such railroad was completed on May 10, 1869. By 1900, four additional transcontinental railroads connected the eastern states with the Pacific Coast.