Steam generator (railroad)

Last updated May 21, 2024

A steam generator is a type of boiler used to produce steam for climate control and potable water heating in railroad passenger cars. The output of a railroad steam generator is low pressure, saturated steam that is passed through a system of pipes and conduits throughout the length of the train.

Steam generators were developed when diesel locomotives started to replace steam locomotives on passenger trains. In most cases, each passenger locomotive was fitted with a steam generator and a feedwater supply tank. The steam generator used some of the locomotive's diesel fuel supply for combustion. When a steam generator-equipped locomotive was not available for a run, a so-called "heating car" fitted with one or two steam generators was inserted between the last locomotive in the consist and the rest of the train.

Steam generators would also be fitted to individual cars to enable them to be heated independently of any locomotive supply.

In Ireland, Córas Iompair Éireann used "heating cars" as standard and CIÉ diesel locomotives were not fitted with steam generators.

Background

Solid fuel

In the first decades of passenger railroading, cars were heated by a wood or coal fired stove if heated at all. It was difficult to evenly heat the long, drafty cars, and passengers near the stove often found it uncomfortably hot, while those further away gained little heat at all. The stoves were also a safety hazard; cars were often ignited by embers from the stove, especially in a wreck, when a dislodged stove would overturn, dumping burning coals into the car.

High pressure steam

The use of steam from the locomotive to heat cars was first employed in the late 19th century. High pressure steam from the locomotive was passed through the train via pipes and hoses. The dangers of this arrangement became evident in the accidents that plagued the industry.

Low pressure steam

In 1903, Chicago businessman Egbert Gold introduced the "Vapor" car heating system, which used low pressure, saturated steam. The Vapor system was safe and efficient, and became nearly universal in railroad applications.

Introduction of the steam generator

When steam locomotives began to be retired from passenger runs, Gold's company, now known as the Vapor Car Heating Company, developed a compact water-tube boiler that could be fitted into the rear of a diesel locomotive's engine room. Known as the Vapor-Clarkson steam generator, it and its competitors (notably the unit built by Elesco) remained a standard railroad appliance until steam heat was phased out.

In 1914–16, the Chicago, Milwaukee & St Paul Railway electrified some 440 miles (710 kilometres) of their line going over the Rocky Mountains and Cascade Range with the 3 kV DC overhead system. The motive power was EF-1s and EP-1s by American Locomotive Company (Alco) with electrical equipment by General Electric. These articulated 2-section engines in passenger version were equipped with 2 oil-fired steam boilers, one in each section.^[1]

In Great Britain, steam generators were built for British Railways diesel locomotives ^[2] by three firms - Spanner,^[3] Clayton^[4] and Stone.^[5] All types were notoriously unreliable and failures were very common.^{[ citation needed ]}

In Poland, vapor steam generators were fitted to diesel passenger locomotives of the SP45 class. The boilers were removed in the 80s and 90s and replaced with 3 kV DC generators driven by main engine, when maintenance became too expensive and remaining cars not fitted with electric heating were withdrawn from service.

The New Zealand, electric locomotives class ED, used in and around Wellington, were fitted with oil-fired steam boilers manufactured by the Sentinel Waggon Works. The boilers appeared to have been used very rarely and were removed during the locomotives’ operational lives.

Steam generator types

Oil-fired

These burned diesel fuel, which is a lightweight fuel oil. The term steam generator (as opposed to boiler) usually refers to an automated unit with a long spiral tube that water is pumped through and is surrounded by flame and hot gases, with steam issuing at the output end. There is no pressure vessel in the ordinary sense of a boiler. Because there is no capacity for storage, the steam generator's output must change to meet demand. Automatic regulators varied the water feed, fuel feed, and combustion air volume.

By pumping slightly more water in than can be evaporated, the output was a mixture of steam and a bit of water with concentrated dissolved solids. A steam separator removed the water before the steam was fed to the train. An automatic blowdown valve would be periodically cycled to eject solids and sludge from the separator. This reduced limescale buildup caused by boiling hard water. Scale build-up that occurred had to be removed with acid washouts.

The New Zealand ED class (1,500 volts) electric locomotive used around Wellington from 1940 originally had oil-fired water tube boilers for passenger carriage steam heaters, which were later removed. Initially diesel-hauled passenger trains like the Northerner on the North Island Main Trunk had a separate steam heating van, but later the carriages of long-distance trains like the Overlander used electric heaters supplied by a separate power or combined power-luggage van.

Electrically-heated

In British electric locomotives the steam generator was usually an electric steam boiler, heated by a large electric immersion heater running at the (then) line voltages of 600 volts from a third rail or 1,500 volts from an overhead wire.

The Polish electric locomotive EL204 of 1937 was fitted with an electric steam generator supplied from overhead lines.^[6] The locomotive was destroyed during the second world war.

Modern times

Steam heated or cooled rail cars have been largely replaced or converted to fully electric systems. Wisps of steam issuing from normal service cars are now history in the UK, US, Canada, and much of the rest of the world.

In the UK, much preserved stock, including main-line certified railtour sets, still retains steam heating capability as well as electric heating, and this is still sometimes used when the trains are being operated by steam locomotives or preserved diesels which have had their steam generators restored to service. The Scottish Railway Preservation Society's main-line registered set of Mk1 railtour coaches are dual heat, and one of their Class 37s^{[ which? ]} has had its boiler, removed in the 80s, replaced and returned to service to provide steam heat on main line tours.

Virtually all private, tourist and heritage preserved railways use BR MkI and MkII coaches, most of which are heated by steam. Some later build MkII, and some MkI's have been modified have dual-heat capability (steam and electric). An increasing number of heritage lines have electric heat capable locomotives.

The Grand Canyon Railway of Williams, Arizona, still uses steam generators to keep coaches powered when their older diesels and steam locomotives are pulling the train.

Related Research Articles

<span class="mw-page-title-main">Locomotive</span> Self-propelled railway vehicle

A locomotive or engine is a rail transport vehicle that provides the motive power for a train. If a locomotive is capable of carrying a payload, it is usually rather referred to as a multiple unit, motor coach, railcar or power car; the use of these self-propelled vehicles is increasingly common for passenger trains, but rare for freight trains.

A boiler is a closed vessel in which fluid is heated. The fluid does not necessarily boil. The heated or vaporized fluid exits the boiler for use in various processes or heating applications, including water heating, central heating, boiler-based power generation, cooking, and sanitation.

A steam locomotive is a locomotive that provides the force to move itself and other vehicles by means of the expansion of steam. It is fuelled by burning combustible material to heat water in the locomotive's boiler to the point where it becomes gaseous and its volume increases 1,700 times. Functionally, it is a steam engine on wheels.

A tender or coal-car is a special rail vehicle hauled by a steam locomotive containing its fuel and water. Steam locomotives consume large quantities of water compared to the quantity of fuel, so their tenders are necessary to keep them running over long distances. A locomotive that pulls a tender is called a tender locomotive. Locomotives that do not have tenders and carry all their fuel and water on board the locomotive itself are called tank locomotives or tank engines.

A diesel locomotive is a type of railway locomotive in which the power source is a diesel engine. Several types of diesel locomotives have been developed, differing mainly in the means by which mechanical power is conveyed to the driving wheels. The most common are diesel-electric locomotives and diesel-hydraulic.

A water trough, or track pan, is a device to enable a steam locomotive to replenish its water supply while in motion. It consists of a long trough filled with water, lying between the rails. When a steam locomotive passes over the trough, a water scoop can be lowered, and the speed of forward motion forces water into the scoop, up the scoop pipe and into the tanks or locomotive tender.

Water heating is a heat transfer process that uses an energy source to heat water above its initial temperature. Typical domestic uses of hot water include cooking, cleaning, bathing, and space heating. In industry, hot water and water heated to steam have many uses.

A central heating system provides warmth to a number of spaces within a building from one main source of heat. It is a component of heating, ventilation, and air conditioning systems, which can both cool and warm interior spaces.

The British Rail Class 47 or Brush Type 4 is a class of diesel-electric locomotive that was developed in the 1960s by Brush Traction. A total of 512 Class 47s were built at Brush's Falcon Works in Loughborough and at British Railways' Crewe Works between 1962 and 1968, which made them the most numerous class of British mainline diesel locomotive.

In the early hours of 6 July 1978, a fire broke out in a sleeping car train near Taunton, Somerset, England. 12 people were killed and 15 were injured. The fire was caused by an electric heater that had been obstructed by sacks of dirty bed linen, causing it to overheat. Most deaths were due to smoke inhalation.

In rail transport, head-end power (HEP), also known as electric train supply (ETS), is the electrical power distribution system on a passenger train. The power source, usually a locomotive at the front or 'head' of a train, provides the electricity used for heating, lighting, electrical and other 'hotel' needs. The maritime equivalent is hotel electric power. A successful attempt by the London, Brighton and South Coast Railway in October 1881 to light the passenger cars on the London to Brighton route heralded the beginning of using electricity to light trains in the world.

An SDP40 is a 6-axle passenger diesel-electric locomotive built by General Motors Electro-Motive Division (EMD) between June 1966 and May 1970.

A gas turbine locomotive is a type of railway locomotive in which the prime mover is a gas turbine. Several types of gas turbine locomotive have been developed, differing mainly in the means by which mechanical power is conveyed to the driving wheels (drivers). A gas turbine train typically consists of two power cars, and one or more intermediate passenger cars.

The NZR ED class locomotive was a type of electric locomotive used in Wellington, New Zealand. They were built by English Electric and the New Zealand Railways Department (NZR) between 1938 and 1940, and hauled mainly passenger trains on the Wellington region's 1500 V DC electrification, and banked freight trains on the steep section between Paekākāriki and Pukerua Bay.

Pennsylvania Railroad Class L1s were 2-8-2 "Mikado"-type steam locomotives that were used on the Pennsylvania Railroad during the early twentieth century. These 574 locomotives were manufactured between 1914 and 1919 by the railroad's own Juniata Shops as well as the Baldwin Locomotive Works (205) and the Lima Locomotive Works (25).

<span class="mw-page-title-main">DB Class 215</span>

The DB Class 215 is a 4 axle diesel locomotive of the V 160 type. They were built for the German Federal Railways for medium-weight passenger and freight service on secondary and primary routes, and later passed to the Deutsche Bahn AG.

An electric-steam locomotive is a steam locomotive that uses electricity to heat the water in the boiler to create steam instead of burning fuel in a firebox. This is a highly unusual type of locomotive that only makes economic sense under specific conditions. Normally, it would be much more efficient to build and use an electric locomotive. However, lack of time and resources, lack of coal or similar fuel, and the presence of relatively cheap and available electricity may make conversion of an existing steam locomotive into an electric-steam locomotive a viable proposition.

The Great Northern Railway (GNR) Class L1 was a 0-8-2T side tank steam locomotive designed by Henry Ivatt. It was originally designed for suburban passenger traffic on the Metropolitan City Lines.

The ČD 749 class is a diesel electric locomotive, created through refurbishment of classes 751 and 752.

The Dongfeng diesel multiple unit, also known as the Dongfeng motor coach, and NM1, was a DMU of Ministry of Railways, and was also the first diesel-hydraulic power car and double deck passenger car of China, built by Qingdao Sifang in 1958. The train consisted two motors and four double deck trailers, and was designed for short, commuter services. Each motor has two DV12A high speed diesel engines, and has the SF2006-1 hydraulic transmission. As the set had numerous flaws, it never entered mass production, but the valuable experience gained in the design and manufacturing process was later applied to the DFH1 and Red Star-class locomotive, while the passenger cars designs were later further developed for double deck trains such as the NZJ.

References

↑ An Epoch in Railway Electrification (PDF). Schenectady, NY, USA: General Electric Company. July 1916. p. 27. The passenger and freight locomotives are identical, with the exception of gear ratio and the addition of an oil-fired steam boiler in each half of the passenger locomotives for heating the trailing coaches. The two boilers are capable of evaporating 4000 pounds of water per hour and this equipment with tanks for oil and water bring the weight of the locomotive up to approximately 300 tons.
↑ "31162, 31225, Spanner Mk 1 Boilers & Steam". www.a1alocomotives.co.uk. Archived from the original on 2008-08-27.
↑ "Locomotive Repair Books, Record Cards, Manuals and Driver's Handbooks".
↑ "How Steam is Produced in a Clayton Steam Generator". Archived from the original on 2003-04-12. Retrieved 2009-10-04.
↑ "Locomotive Repair Books, Record Cards, Manuals and Driver's Handbooks".
↑ "Lokomotywa elektryczna EL-200 (EL-200 Class Electric Locomotive)" (in Polish). Archived from the original on 8 March 2009. Retrieved 6 February 2012.

External links

A web site devoted to locomotive steam generators

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] An Epoch in Railway Electrification (PDF). Schenectady, NY, USA: General Electric Company. July 1916. p. 27. The passenger and freight locomotives are identical, with the exception of gear ratio and the addition of an oil-fired steam boiler in each half of the passenger locomotives for heating the trailing coaches. The two boilers are capable of evaporating 4000 pounds of water per hour and this equipment with tanks for oil and water bring the weight of the locomotive up to approximately 300 tons.

[2] "31162, 31225, Spanner Mk 1 Boilers & Steam". www.a1alocomotives.co.uk. Archived from the original on 2008-08-27.

[3] "Locomotive Repair Books, Record Cards, Manuals and Driver's Handbooks".

[4] "How Steam is Produced in a Clayton Steam Generator". Archived from the original on 2003-04-12. Retrieved 2009-10-04.

[5] "Locomotive Repair Books, Record Cards, Manuals and Driver's Handbooks".

[6] "Lokomotywa elektryczna EL-200 (EL-200 Class Electric Locomotive)" (in Polish). Archived from the original on 8 March 2009. Retrieved 6 February 2012.

[1]

[2]

[3]

[4]

[5]

[6]