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Helper engine

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Helper engine

A bank engine (United Kingdom/Australia) (colloquially a banker) or helper engine or pusher engine (North America) is a railway locomotive that temporarily assists a train that requires additional power or traction to climb a grade (or bank). Helpers/bankers are most commonly found in mountain divisions (called "helper districts" in the U.S.), where the ruling grade may demand the use of substantially greater motive power than that required for other grades within the division.

Historic practice

Helpers/bankers were most widely used during the age of steam, especially in the American West, where significant grades are common and trains are long. The development of advanced braking systems and diesel-electric or electric locomotives has eliminated the everyday need for bankers/helpers in all but a few locations.

Bankers or helpers were historically positioned at the rear of the train, in which case they also protected against wagons or coaches breaking away from the train and running back downhill. Also, in a pusher role, it was possible for the helper/banker to easily separate once the train had crested the grade. Once separated, the banker would return to a siding or stub so as to clear the mainline and get ready for the next train. A common practice with knuckle couplers was to remove the knuckle from the front coupler. The locomotive would be brought up behind the last car of the train while the train was moving slowly. The air brake hose would not be coupled. When the train no longer required assistance, the helper/pusher would slow, then reverse and coast back down the grade to its siding at the bottom of the grade. This practice was outlawed in North America after the end of the steam era.

Special heavily constructed cabooses were sometimes used in helper areas. Ordinary cabooses were built as lightly as practical and might be crushed by the helper/pusher's force, which could be as much as 90 tons. The heavy cabooses allowed crews to avoid the time-consuming procedure of splitting the train just ahead of the caboose.[1]

Pushers/helpers were commonly designed to provide extreme power for very short runs; as a result they could not push at full power for very far before steam pressure dropped. But if it could push enough to get the train to the top of the grade, then it could build up pressure while coasting back down and while waiting for the next train to come along. This practice was common in Europe.

Since it was not possible to remotely control a steam locomotive, each helper had to have a full crew on board. Careful coordination was required between engine crews to assure that all locomotives were operated in a consistent manner. Standard whistle signals were employed to tell the helper crew when to apply power, drift or brake. A misunderstanding of signals by a pusher locomotive crew could result in a major wreck if the lead locomotive applied brakes while the bank engine was still applying power. The usual result was that the train would experience a violent run-in (an abrupt bunching of train slack), resulting in the derailment of part or all of the train.

The town of Helper, Utah was named after these engines, as it was where helper engines were kept to assist on the climb to Soldier Summit.

Modern practice

Nowadays helpers/bankers are often controlled by coded radio signals from the locomotive at the head end of the train, allowing one engineer (driver) to simultaneously control the helper(s) and the train being helped. If radio operation is not possible, electrical control might be used, by way of cables running the length of the train (especially in case of passenger trains), or else the helpers are manually controlled, which is still the norm for bank engines at the end of freight trains in Europe.

At the front

In the UK, an engine that was temporarily attached to the front of a train to assist with the ascent of an incline was called a pilot locomotive. This differentiated it from the train engine(s) which was provided to power the train to its destination. A train with one or more helper locomotives attached to the front may be referred to as a "double header", "triple header", etc., depending on the number of helpers/bankers. These terms gradually fell out of general usage as diesel locomotives replaced steam power.


In countries where buffers-and-chain couplers are used, bank engines often cannot be added to the front of the train due to the limited strength of the couplers; In the case of standard UIC couplers and a maximum grade of 28 (which is common e.g. for lines through the Alps), the limit is a train weight of 1400 tons;[2] if a train is heavier, bank engines have to be added in the middle or to the end of the train in order not to exceed the maximum load for any coupler.

Adding locomotives in the middle of the train has the distinct advantage of applying the helper power to only part of the train, thus limiting the maximum drawbar pull applied to the first car of the train to a safe level. The narrow gauge portions of the Denver and Rio Grande Western Railroad, in particular, used "swing helpers," which meant the helper locomotives were placed mid-train at a point where they were pushing and pulling an approximately equal amount of tonnage, said location being referred to as the train's "swing point". This was also done to balance out the "slack" in the train between the locomotives, the swing helpers, and the end train helpers just in front of the caboose. However, this arrangement requires splitting the train in order to add or remove the helper engine(s), which can be a time-consuming maneuver. However on some American railroads it was necessary to an extent because operating rules required end of train helpers to be added at the end of the train, but in front of the caboose. This was done for the safety of the train crew riding inside the caboose.

End of the train

To be able to add and remove helper locomotives quickly, which is especially important in Europe due to the high traffic density, they are usually added to the end of the train. Normally they are coupled and the air hoses are connected, which is necessary for the air brake to work correctly e.g. in emergency situations, but in special cases trains are banked with uncoupled locomotives, which can be added or removed "in-flight." In the UK it was a usual practice for banking locomotives to follow and buffer-up to a slow-moving assisted freight train without coupling (as demonstrated in archive films of banking on the Lickey Incline) before applying more power, thus avoiding a standing start. This procedure is not performed in North America as it would violate Canadian and US safety regulations.


The following are locations where bankers are, or were, frequently required:



New South Wales




  • Liège-Guillemins - (32 ‰) Banking of some hauled passenger trains heading towards Brussels between Liège-Guillemins and Ans. Freight trains are not allowed on this section.


  • Maurienne Valley line, the main line from France to Italy through the Alps - Frequent electric banking services for freight trains - 30‰ .


  • Spessart Ramp between Aschaffenburg and Würzburg in northern Bavaria
  • Schiefe Ebene between Neuenmarkt-Wirsberg and Marktschorgast in Northern Bavaria

The Royal Bavarian Railways developed special 0-8-8-0 mallet banking locomotives: series Gt 2 x 4/4



  • Opicina Tramway in Trieste - bankers on a 260‰ funicular section of the line


  • "Senohachi" section (Seno - Hachihommatsu) of the Sanyo Main Line - Dedicated JNR Class EF67 and EF210-300 electric locomotives assist heavy freight trains from the rear.
  • Usui Pass on the Shinetsu Line - The maximum grade of 66.7‰ (1 in 15) necessitated the use of helper locomotives on all trains, including EMUs, both uphill and downhill (for added braking ability). A pair of JNR Class EF63 electric locomotives were coupled at the downhill side of every train. This segment was closed upon the opening of the Nagano Shinkansen in 1997.


  • Distrito Acultzingo (Orizaba - Jesus de Nazareno) - 2.7% line built to replace the 4% Maltrata District, today operated by Ferrosur notable for use of mid-train helper locomotives and helpers on the rear, all operated by radio control from the leading locomotives.[3][4]

New Zealand

Banking by diesel-electric locomotives is also used on all steam train excursions that travel between Tauranga and Matamata on the East Coast Main Trunk, Featherston and Upper Hutt on the Wairarapa Line, and Arthur's Pass and Otira on the Midland Line. This is due to steam operation being too dangerous within the confinements of tunnels on those sections of line.


  • Bolan Pass Railway between Aab-i-Gum and Kolpur
  • Khyber Pass Railway

Sri Lanka


  • Gotthard line - 27. Frequent electric banking services for freight trains, SBB-CFF-FFS and others
  • Lötschberg line - 27‰. Frequent electric banking services until the opening of the Lötschberg Base Tunnel in June 2007; now most of heavy trains use the base tunnel (maximum 15‰ on northern approach) and bank engines are less frequently used; BLS, SBB-CFF-FFS and others
  • Südostbahn between Pfäffikon SZ and Arth-Goldau - 52‰. Electric banking services (using locomotives or EMUs) often necessary when the Voralpenexpress has additional coaches
  • Monte Ceneri Pass line (part of the Gotthard line) - 28‰ northern ramp, 20‰ southern ramp. Frequent electric banking services, SBB-CFF-FFS and others

United Kingdom

United States


See also


External links

  • Ghost Depot's entry for Soldier Summit. This page has a photo of a 4-header train with rear helper on the western approach to Soldier Summit
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