Hubbry Logo
Barrier vehicleBarrier vehicleMain
Open search
Barrier vehicle
Community hub
Barrier vehicle
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Barrier vehicle
Barrier vehicle
Barrier vehicle
View on Wikipedia
from Wikipedia

A preserved example of a translator carriage - at the Downpatrick and County Down Railway in Ireland, the former NI Railways DBSO is used to allow a 141 Class diesel locomotive with buffers and chain couplers to haul a 450 Class railcar with tightlock couplers.

A barrier vehicle (BV), barrier wagon, match wagon or translator coach is used to convert between non-matching railway coupler types. This allows locomotives to pull railway vehicles or parts of a train with a different type of coupler. A match wagon has an identical dual coupling at both ends.

Use

[edit]

They are often found on empty coaching stock moves where freight locomotives need to transport coaching stock fitted with Scharfenberg couplers and other automatic couplers. The use of barrier coaches has evolved with a general move from conventional passenger trains consisting of locomotive-hauled coaches, to trains consisting of multiple units.

Liveries

[edit]

These vehicles tend to be neutrally liveried or in some cases are painted with the livery of a particular rolling stock company. For example, Porterbrook use corporately-liveried examples for delivery of rolling stock and for transfers for refurbishment and maintenance.[1]

[edit]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Barrier vehicle

View on Grokipedia
from Grokipedia
A barrier vehicle, also known as a barrier wagon or translator coach, is a specialized type of railway designed to enable the connection of locomotives or other vehicles with incompatible coupler systems by incorporating adaptable or dual mechanisms at each end. These vehicles are essential for forming mixed consists in scenarios such as hauling, testing, or transporting across networks where standard couplers like screw, buckeye, or automatic types do not match. In modern UK railway operations, as of 2022, barrier vehicles often feature advanced universal coupling systems with interchangeable heads, such as , Latch Type 10+136, Tightlock, or Wedgelock, allowing compatibility with diverse train formations including electric multiple units () and diesel locomotives. They support critical activities like vehicle commissioning, rescue missions, and network-wide movements, with recent upgrades including brake interface units compatible with systems like Alstom's Aventra EMU Train Control and Management System (TCMS) to eliminate the need for additional brake force vehicles. Companies such as Meridian Generic Rail Limited provide these vehicles for , emphasizing their role in reducing track access charges and enhancing operational efficiency. Historically, the term "barrier vehicle" or "barrier wagon" originated in British Railways practices for safety purposes, particularly in freight trains carrying hazardous materials like explosives. In such cases, empty wagons or those loaded with non-inflammable, non-explosive goods served as buffers to separate dangerous cargo from the and , preventing potential chain reactions in accidents; at least two such barriers were required for trains with more than five vehicles of labeled Government explosives. By the late 20th and early 21st centuries, the concept evolved to include safety buffering in passenger services, where stronger or coaches formerly acted as barrier vehicles between locomotives and older coaches (until 2011) to mitigate collision risks and improve under exemptions to the Railway Safety Regulations 1999. This dual role underscores the vehicle's importance in ensuring compatibility and protection across evolving railway standards.

Definition and Terminology

Definition

A barrier vehicle is a specialized item of railway designed to enable the connection and hauling of train consists featuring incompatible coupler systems at each end. These vehicles, also known as match wagons or translator coaches in certain contexts, act as intermediaries to bridge differing coupling mechanisms, allowing seamless integration of locomotives and that would otherwise be unable to couple directly. The core design incorporates a dual coupling setup, with one end fitted with a traditional coupler—such as the buffers and chain system prevalent in freight operations—and the opposite end equipped with a modern or unit-specific coupler, for example, the buckeye or tightlock coupler used on many multiple units. This configuration ensures compatibility across diverse train formations, particularly in mixed operations involving legacy and contemporary equipment. Barrier vehicles play a critical role in averting operational disruptions arising from coupler mismatches, such as those between freight locomotives typically using screw-link couplings and passenger coaching stock employing automatic buckeye systems. By facilitating these connections, they maintain train integrity and efficiency without requiring extensive modifications to existing fleets. Structurally, a barrier vehicle employs a robust or coach body capable of handling the tension and compression forces generated by mismatched systems, often incorporating reinforced underframes to absorb buff and draft loads effectively.

Terminology Variations

Barrier vehicles are referred to by various synonyms that underscore their adaptive role in operations, particularly in bridging incompatible systems. In the freight sector, the term "barrier wagon" is commonly applied, originally denoting a vehicle positioned to isolate wagons carrying from the or other cars, thereby providing a buffer against potential hazards. The nomenclature "barrier vehicle" (often abbreviated as BV) predominates in and Irish contexts, encompassing both freight and passenger applications where the vehicle enables the connection of with mismatched couplers, such as buckeye and types. This usage reflects a of the "barrier" concept from its historical emphasis on physical separation for —dating back to practices in hazardous (detailed in the Historical Development section)—to modern functions centered on mechanical and electrical adaptation for . In passenger services, barrier vehicles may also provide protection, such as stronger or coaches between locomotives and older stock. Another variant, "translator coach," highlights the vehicle's role in converting control systems, especially in scenarios involving electric multiple units (EMUs). This term arises from the need to interface differing and signaling protocols, such as transforming pneumatic signals from a (e.g., 5 bar pressure for release) into electrical commands compatible with like Westcode (e.g., 110V DC signals). For instance, in operations, translator coaches have been employed to haul failed EMUs by providing necessary electrical and pneumatic translations during rescue maneuvers. The term "match wagon" serves as a further synonym, particularly in heritage and preservation settings, where it describes vehicles designed to align and couple disparate ends, echoing the core function of dual couplers for compatibility. Regional preferences further illustrate these variations: "barrier vehicle" remains standard across networks, while "translator coach" gains prominence in EMU-specific adaptations, and Irish operators like Railways have applied "barrier vehicle" to (DBSO) coaches for coupler matching in mixed formations.

Historical Development

Early Uses as Safety Barriers

Barrier vehicles, initially referred to as barrier wagons, emerged during the steam era of British railways before the 1950s as a critical safety measure to maintain a protective distance between locomotives or brake vans and wagons transporting hazardous materials, including explosives, flammable chemicals like petroleum products, and noxious substances such as toxic gases. These wagons served to isolate potentially volatile loads from sources of ignition, such as sparks emitted by steam locomotives during operation, thereby minimizing the risk of accidental detonation or fire in the event of coupling shocks or derailments. For instance, on Class A or B oil trains—classified by their volatility—three or four empty mineral wagons, often of the vacuum-fitted type, were positioned at the engine end, while one or two were placed at the brake van end to create a buffer zone. The regulatory framework underpinning this practice derived from British common carriers legislation, which compelled railways to handle dangerous goods traffic while enforcing protective protocols to prevent chain reactions during accidents. Explosives, in particular, were transported in specialized vans limited to a maximum of five per train during peacetime (increasing to up to 60 in wartime), always separated by barrier wagons to absorb impacts and contain any potential blast propagation. Similarly, shipments of highly toxic substances like hydrocyanic acid were restricted to block trains of no more than five wagons, flanked by at least two barrier wagons and a guarded to ensure compliance with safety spacing requirements. In terms of design, early barrier wagons were rudimentary, consisting of standard empty open wagons (such as 8-plank types) or covered repurposed for the role, lacking specialized coupling mechanisms and prioritizing strong buffers to withstand compressive forces without transmitting them to the hazardous cargo. If dedicated barrier wagons were unavailable, any spare empty vehicle could substitute, though this occasionally complicated operations due to the need for improvisation. These simple configurations emphasized physical separation over advanced , reflecting the era's focus on basic shock absorption in freight formations. The adoption of barrier wagons waned with the shift to diesel and electric traction in the period, as the elimination of steam-generated sparks reduced ignition hazards, and improved handling protocols for further diminished the necessity. By 1962, such wagons were no longer mandated for oil trains, marking a significant phase-out, though routine applications lingered into the and for residual explosive and chemical transports before the practice largely transitioned to other roles. This safety-oriented origin nonetheless influenced subsequent railway vehicle adaptations, embedding the principle of protective isolation in freight operations.

Evolution for Coupler Adaptation

Following , barrier vehicles underwent a significant transformation during the 1950s and 1970s, shifting from primarily safety-oriented roles to critical adapters facilitating the integration of (MU) trains with legacy freight systems and enabling smoother international rail operations across diverse coupler standards. This period saw the proliferation of diesel and electric MUs, which often featured incompatible coupling mechanisms compared to traditional or chain systems on locomotives and wagons, necessitating dedicated adaptation vehicles to maintain operational efficiency without full fleet overhauls. In the , a key milestone occurred in the with the widespread adoption of barrier vehicles for empty stock movements, allowing MUs to be hauled by locomotives using mixed coupling arrangements. This practice became essential as expanded diesel multiple unit services, requiring transitional vehicles to bridge Buckeye couplers on passenger stock with screw couplings on hauling locomotives. The trend accelerated in the 1970s with the introduction of the High Speed Train (HST), authorized for prototype development in mid-1970 and first tested in 1972, where non-standard Buckeye couplers on the HST sets demanded specialized match wagons for attachment to conventional mainline locomotives during maintenance or repositioning. Prior to the HST, similar adaptations were employed in the London Underground for transferring tube stock to mainline networks, using barrier vehicles to accommodate the mechanical differences between subway-specific couplers and standard rail systems. The 1980s and 1990s marked further evolution influenced by widespread across , driving the development of advanced translator designs that addressed not only mechanical coupler mismatches but also electrical incompatibilities, such as varying voltage systems (e.g., 25 kV AC overhead versus 1.5 kV DC ). These translator coaches incorporated jumper cables and interface panels to ensure seamless power transfer between electrified MU formations and non-electrified or differently powered locomotives, supporting the growth of cross-border high-speed and freight services. Globally, barrier vehicles facilitated European cross-border operations by adapting incompatible systems like the Janney knuckle coupler (prevalent in Western freight) to the SA3 Willison coupler (dominant in Eastern networks), often via dedicated coupler wagons or hybrid adapters that combined side buffers with automatic engagement mechanisms. For instance, hybrid SA3 setups with screw coupling (SC) adapters allowed interoperability on routes spanning former borders, reducing shunting times and enhancing freight fluidity. However, ongoing standardization efforts, particularly the European Union's push for Digital Automatic Coupling (DAC) since the , have contributed to a decline in reliance on such vehicles in regions achieving uniform coupler adoption; as of 2025, DAC testing is set to begin in 2026 with up to 100 pioneer trains, aiming for full European rollout by the 2030s. DAC integrates mechanical, electrical, and connections into a single system, potentially eliminating the need for adapters by streamlining wagon interoperability and cutting marshalling times by up to 50% on key corridors.

Design Features

Coupling Mechanisms

Barrier vehicles are designed with dual-ended coupling systems to bridge incompatibilities between different railway coupling standards, typically featuring a traditional buffers-and-chain arrangement at one end and an automatic coupler at the other. The buffers-and-chain system, standard in the UK and much of Europe, consists of side buffers to absorb compression forces and a chain link with a screw coupling for tension, providing a manual, tension-only connection that requires shunting staff to insert and tighten the link by hand. In contrast, the opposite end employs automatic couplers such as the Buckeye (a variant of the Janney knuckle coupler), which handles both compression and tension through a self-locking knuckle mechanism made of cast steel, allowing for quicker and safer coupling without personnel between vehicles. This setup enables barrier vehicles to interface legacy freight or locomotive stock with modern multiple-unit trains, as seen in universal barrier vehicles equipped with interchangeable heads compatible with Dellner Type 10+12 or Tightlock systems. Compatibility across international standards is achieved through specialized adaptations, such as pairing Scharfenberg couplers—common on European multiple units for their compact, rotating disc design handling up to 2,000–2,500 kN compressive forces—with traditional chain links via retractable buffers that swing away to expose the hook. These adaptations prioritize mechanical , with some designs incorporating height-adjustable systems operating from 670 to 1070 mm above rail level to accommodate variations in . Engineering considerations emphasize structural integrity to manage differential forces between coupling types, including reinforced underframes capable of withstanding forces up to 600–1,500 kN and compressive forces of 800–2,500 kN, ensuring even load distribution across axles to minimize risks from longitudinal play limited to under 2 mm. Temporary connections during shunting may use hooks or adaptors to secure the end, with chains as backups on passenger-configured barrier vehicles to prevent uncoupling under impact. Designs often include elastic drawgears to absorb shocks, particularly in mixed formations where rigid couplers meet flexible systems. Limitations of these coupling mechanisms include their unsuitability for high-speed operations due to potential from slack in chain links and higher risks under dynamic loads, restricting use primarily to low-speed hauling, , and shunting at speeds below 15 km/h. Additionally, manual elements in hybrid setups increase labor requirements and safety hazards compared to fully automatic systems.

Additional Equipment

Barrier vehicles incorporate various non-coupling equipment to facilitate safe and efficient hauling of multiple-unit (MU) stock, particularly during dead hauls where the MU units are unpowered. In translator coaches, a key feature is the set, which converts the locomotive's supply—typically 1000 V AC at 75 Hz—into the lower voltage required for the MU's control circuits and systems. This setup ensures that essential functions like and basic controls remain operational without relying on the MU's own power sources. Certain variants, such as (DBSO) types, include a cab at one end equipped for of the , allowing operation in push-pull mode without repositioning the loco. These cabs feature standard driver interfaces, including , controls, and AWS () integration, while lighting and signaling interfaces enable compatibility with the hauled stock's systems for tail lights and marker lights during transit. Safety and utility features are integral to barrier vehicle design, including manual handbrakes for securing the vehicle when stationary, emergency couplers for rapid attachment in breakdowns, and onboard storage compartments for tools and shunting equipment. To enhance stability, particularly on curved tracks, vehicles are designed with optimized weight distribution, often using bolstered bogies that maintain low center of gravity and reduce derailment risk during towing. In modern applications as of the 2020s, designs comply with TSI (Technical Specifications for Interoperability) standards for enhanced pan-European use.

Types and Examples

Match Wagons

Match wagons are a subtype of barrier vehicles used primarily as freight wagons to support rail-mounted cranes by carrying the during transit and providing a platform in goods trains and on heritage railways. These vehicles often feature versatile open or covered bodies, typically on four- or six-wheeled underframes, which allow for the storage of tools, toolboxes, or other gear. Prominent examples include the London and South Western Railway-origin match wagon preserved on the Isle of Wight Steam Railway, believed to date from the 1890s and paired with a six-wheeled hand crane for demonstration and heritage operations. Another is the Southern Railway (SR) match wagon built in 1943 by the Ministry of War Transport (MOWT), numbered DS 3182 and weighing 6.5 tons, which supports a 12-ton hand crane on the Bluebell Railway and remains operational for trackside tasks. In applications, match wagons are confined to low-volume or specialist freight hauls, such as supporting hand cranes in track trains or assisting shunting operations with industrial locomotives on heritage lines. Their use facilitates safe transport of over short distances, emphasizing reliability in preservation-era scenarios rather than high-speed or mainline services.

Translator Coaches

Translator coaches represent a specialized of passenger into barrier vehicles, primarily converted from coaches or (EMU) driving vehicles to facilitate the hauling of non-compatible dead EMUs or multiple units during maintenance or transfer operations. These conversions enable the provision of appropriate interfaces and electrical jumpers to translate between systems and EMU control wiring, allowing safe and efficient movement of stock that would otherwise require incompatible attachments. Prominent examples include the translator sets T5 and T7, utilized for dead stock movements across the network. Set T5 comprises vehicles 975974 (formerly Mark 1 coach 1030) and 975978 (formerly Mark 1 coach 1025), both converted for hauling and based at ; they have supported trials such as the June 2011 run from Eastleigh to hauling a Class 508 unit, as well as transfers of Class 507/508 and Southeastern Class 465/466 units for refurbishment between 2004 and 2010. As of 2022, T5 was used for Class 318 transfers to . Set T7 consists of ex-Class 508 driving motor vehicles 64664 (named "Liwet" in July 2016, de-named by September 2025; previously "James D Rowlands") and 64707 (named "Labezerin" in July 2016, de-named by September 2025; previously "Sir David Rowlands"), converted specifically for stock drags and frequently employed by GBRf in formations with locomotives like Class 690 for relocations. In 2025, T7 vehicles received a light grey repaint at , followed by application of green and grey EPR . Another notable instance is the Northern Ireland Railways (NIR) Driving Brake Standard Open (DBSO) vehicle 8918, a converted Mark 2F Brake Standard Open originally built in 1974, now operational at the Downpatrick and County Down Railway since 2018. This coach serves as a translator by linking 141 Class diesel locomotives (equipped with screw-shackle couplings) to 450 Class diesel multiple units (using buckeye couplings), enabling mixed formations for heritage operations. Design adaptations in translator coaches often retain original passenger interiors for potential occasional revenue use, though the primary emphasis is on electrical translation capabilities, such as jumper cables for auxiliary power and control systems. These vehicles have been integral to depot activities, supporting transfers of Networker-class units like Class 365 during overhauls in the 1990s through the 2020s.

Operational Applications

Empty Stock Movements

Barrier vehicles are primarily employed in empty coaching stock (ECS) movements to enable freight locomotives, equipped with screw couplings incompatible with passenger auto-couplers such as buckeye or Scharfenberg types, to position unladen between depots and stations. This core application facilitates the efficient relocation of without requiring passenger-specific traction, particularly in networks operating mixed fleets where dedicated multiple-unit locomotives may not be available. In operational procedures, the barrier vehicle is positioned at the head or rear of the consist to serve as an interface between the and the coaching stock, ensuring secure while maintaining continuity across the formation. These movements are classified under empty coaching stock trains (typically Class 4 or 5), necessitating testing, door closure verification, and notification to the for signaling coordination. Due to the non-standard formation and potential partial fitting, speed limits are restricted to 35 mph for non-fully fitted configurations, with further restrictions for unfitted ones not below 35 mph as per current standards (historically 25 mph in some cases). The use of barrier vehicles in ECS movements offers significant benefits as a cost-effective solution compared to deploying specialized multiple-unit locomotives, supporting routine daily servicing and repositioning in diverse rail operations. This approach enhances operational flexibility, particularly for third-party relocations, by leveraging existing freight resources to augment brake force and ensure safe hauling. Challenges in these operations include providing adequate weather protection for exposed passenger stock during transit and meticulous coordination with signaling systems to accommodate the non-standard train characteristics, preventing disruptions in mixed-traffic environments. Translator coaches, for instance, exemplify barrier vehicle adaptations specifically suited for ECS positioning of modern multiple units.

Maintenance and Transfer

Barrier vehicles play a crucial role in specialized hauls for transporting electric multiple units (EMUs) or individual coaches between facilities across the rail network. For instance, former driving motor standard (DMS) vehicles, such as numbers 64664 and 64707 converted in 2013-2014 from withdrawn unit 508207, serve as translator coaches specifically for the movement of EMU stock to and from depots like . These conversions enable the safe attachment of locomotives to incompatible EMU consists during non-routine transfers, such as overhauls or fault-free running tests, ensuring compatibility between buckeye couplers on EMUs and traditional screw-link systems on hauling locomotives. In preservation and heritage contexts, barrier vehicles facilitate similar transfers on smaller networks. At the Downpatrick and County Down Railway in , the Northern Ireland Railways (NIR) Driving Brake Standard Open (DBSO) vehicle No. 8918, acquired in 2014 and operational since 2018, functions as a translator to connect shackle-coupled locomotives to the buckeye-equipped 450 Class No. 458. This setup allows for the hauling of the during maintenance operations or repositioning within the site's facilities. Logistically, these operations typically involve pairing barrier or translator vehicles with dedicated support locomotives, such as Class 66 diesels operated by freight companies like , to handle full consists over long distances. Translator pairs are often incorporated at both ends of an formation to maintain and electrical continuity, particularly during cross-network hauls between regional depots. Post-2010, the use of barrier vehicles has seen increased application in by leasing and operations specialists, driven by ongoing cascade programs and rotations among train operating companies. Organizations like , established in 2014, have developed services for stock modifications, refurbishments, and transfers, often using modified locomotives with built-in coupler and that reduce reliance on traditional barrier vehicles. As of the 2020s, this reflects broader industry shifts toward efficient asset utilization amid fleet renewals.

Identification and Liveries

Visual Markings

Barrier vehicles in the rail network are fitted with standardized visual markings to facilitate safe identification, particularly during shunting and coupling procedures where mismatched couplers could lead to accidents. These markings include prominent panels or full ends on the vehicle body to enhance visibility from a distance, especially in poor weather or low-light conditions. Specific labels such as "Barrier Vehicle" or "Translator Vehicle" are stencilled in white or black lettering on the sides of the vehicle to clearly denote their role in bridging incompatible types. codes, which classify the vehicle type, and load limits are stencilled on the sides in accordance with RIS-2453-RST requirements for vehicle registration, marking, and numbering on the mainline network. To mitigate risks associated with coupler incompatibility, safety indicators such as hazard warning labels are applied near the coupling points, cautioning against improper connections between differing systems like buckeye and instanter couplers. Reflective tape is affixed to ends and edges to improve visibility during night-time or low-visibility shunting operations, reducing the likelihood of collisions. These markings comply with Railway Group Standards, including GM/RT2190 for coupler compatibility and interconnectors, which mandate clear identification to prevent coupling errors and ensure operational across the network. On heritage railways, variations in markings may occur to reflect historical practices, preserving authenticity while maintaining basic visibility requirements.

Common Liveries

Barrier vehicles leased by companies such as are typically painted in the owner's corporate colors to denote ownership and facilitate stock movements. 's scheme features a body with lower panels and underframes, applied to HST barrier coaches like GSA 6396 for new train deliveries. This livery, introduced post-privatisation, replaced the standard blue used on earlier barrier vehicles, such as certain Mk1 and Mk4 types that retained BR blue and until disposal or conversion. Departmental operators also apply distinctive schemes to their barrier vehicles for identification in maintenance and transfer duties. The Railway Operations Group (ROG) uses a blue livery on converted Mk2 coaches and HST barriers, exemplified by GSA 6340 (975678), aiding fleet tracking during rail operations. In Northern Ireland, NI Railways employs maroon on its DBSO barrier vehicles, such as those converted for push-pull services, aligning with the operator's traditional coaching stock colors for local haulage. Preservation groups on heritage lines often retain historical liveries on surviving barrier vehicles, preserving pre-nationalisation aesthetics without modern leasing markings. These liveries serve primarily for visual fleet recognition during empty stock workings and , enabling rapid identification of and status across networks, though they have no direct bearing on the vehicles' protective or functions. Examples from the highlight how such schemes support efficient departmental transfers, as seen in their use on Mk2-based barriers.

References

  1. https://www.dellner.com/news/the-universal-barrier-vehicles-ready-for-lease-now
  2. http://filestore.limitofshunt.org.uk.s3.amazonaws.com/supplementary-operating-instructions/br-ner/1959-03-07.pdf
  3. https://www.orr.gov.uk/media/20403/download
  4. https://www.orr.gov.uk/sites/default/files/om/mark-1-followup-letter.pdf
  5. https://www.meridian-generic-rail.co.uk/services/universal-barrier-vehicles/
  6. https://www.voith.com/corp-en/connection-components-couplings/railway-couplers.html
  7. https://patents.google.com/patent/GB2448318A/en
  8. http://www.railway-technical.com/glossary/
  9. http://igg.org.uk/rail/7-fops/fo-expchem.htm
  10. https://features.rcts.org.uk/wp-content/uploads/preserved-coaches/2015/Preserved_Coaching_Stock_of_British_Railways_-_Part_One_-_Jan_2015.pdf
  11. https://www.dbcargo.com/rail-de-en/logistics-news/DAK-final-gauge-series-ready-freight-trains-BMDV-13219296
  12. http://www.railway-technical.com/archive/design-details-of-railways.pdf
  13. https://ec.europa.eu/research/participants/documents/downloadPublic?documentIds=080166e5b0be793f&appId=PPGMS
  14. https://www.artc.com.au/uploads/TA20-Section-12.pdf
  15. https://www.keymodelworld.com/article/br-mk2-dbsos
  16. https://sremg.org.uk/proto/BRSCarriages1_5.pdf
  17. https://en.wiktionary.org/wiki/match_wagon
  18. https://www.bluebell-railway.co.uk/bluebell/cw_news/hand_crane.html#match
  19. https://iwsteamrailway.co.uk/heritage/our-rolling-stock/historic-wagons/
  20. https://victorianweb.org/technology/railways/iow/7.html
  21. https://www.bluebell-railway.com/brps/rolling-stock/wagon-stock-list/
  22. https://www.railwaymagazine.co.uk/12685/north-tyneside-03-prepared-for-gateshead-shunter-reunion/
  23. https://www.bluebell-railway.co.uk/bluebell/pics/12tonhandcrane.html
  24. https://www.departmentals.com/departmental/975974
  25. https://www.departmentals.com/departmental/64664
  26. https://www.departmentals.com/departmental/975978
  27. https://www.departmentals.com/departmental/64707
  28. https://alanthomsonsim.com/downloads/t7-emu-translator-coaches/
  29. https://www.downrail.co.uk/rollingstock/dbso/
  30. https://www.rmweb.co.uk/forums/topic/108758-kellys-projects-sr-emus-wagons-and-conversion-projects/
  31. https://www.modernrailways.com/article/empty-stock-mover-expands
  32. https://consultations.rssb.co.uk/_entity/sharepointdocumentlocation/eda0ea01-c2c7-ec11-a7b6-0022489f4736/2ab10dab-d681-4911-b881-cc99413f07b6?file=09_b_GERT8000_TW1_compressed.pdf
  33. http://filestore.limitofshunt.org.uk.s3.amazonaws.com/periodical-operating-notices/br-er/nd-1989-04-01.pdf
  34. https://www.southernelectric.org.uk/departmental-stock/
  35. https://railopsgroup.co.uk/services/
  36. http://25kv.uk/
  37. https://www.fox-transfers.co.uk/intercity-small-embellishments-2
  38. https://www.ltsv.com/rd/pdfs/tops_list_pdf.php
  39. https://www.rssb.co.uk/standards-catalogue/CatalogueItem/ris-2453-rst-iss-2-1
  40. https://www.rssb.co.uk/standards-catalogue/CatalogueItem/GMRT2190-Iss-3
  41. https://www.networkrail.co.uk/wp-content/uploads/2018/12/NR_CAT_STP_001-Issue-110.pdf
  42. https://www.departmentals.com/departmental/6396
  43. https://www.departmentals.com/departmental/975653
  44. https://www.departmentals.com/departmental/6357
  45. https://www.departmentals.com/departmental/6340
Add your contribution
Related Hubs
User Avatar
No comments yet.