fbpx
Wikipedia

Water-tube boiler

March 27, 2023

A high pressure watertube boiler[1] (also spelled water-tube and water tube) is a type of boiler in which water circulates in tubes heated externally by the fire. Fuel is burned inside the furnace, creating hot gas which boils water in the steam-generating tubes. In smaller boilers, additional generating tubes are separate in the furnace, while larger utility boilers rely on the water-filled tubes that make up the walls of the furnace to generate steam.

Schematic diagram of a marine-type watertube boiler

The heated water/steam mixture then rises into the steam drum. Here, saturated steam is drawn off the top of the drum. In some services, the steam passes through tubes in the hot gas path, (a superheater) to become superheated. Superheated steam is defined as steam that is heated above the boiling point at a given pressure. Superheated steam is a dry gas and therefore is typically used to drive turbines, since water droplets can severely damage turbine blades.

Saturated water at the bottom of the steam drum returns to the lower drum via large-bore 'downcomer tubes', where it pre-heats the feedwater supply. (In large utility boilers, the feedwater is supplied to the steam drum and the downcomers supply water to the bottom of the waterwalls). To increase economy of the boiler, exhaust gases are also used to pre-heat combustion air blown into the burners, and to warm the feedwater supply in an economizer. Such watertube boilers in thermal power stations are also called steam generating units.

The older fire-tube boiler design, in which the water surrounds the heat source and gases from combustion pass through tubes within the water space, is typically a much weaker structure and is rarely used for pressures above 2.4 MPa (350 psi). A significant advantage of the watertube boiler is that there is less chance of a catastrophic failure: there is not a large volume of water in the boiler nor are there large mechanical elements subject to failure.

A water tube boiler was patented by Blakey of England in 1766 and was made by Dallery of France in 1780.[2]

Applications

"The ability of watertube boilers to be designed without the use of excessively large and thick walled pressure vessels makes these boilers particularly attractive in applications that require dry, high-pressure, high-energy steam, including steam turbine power generation".[3]

Owing to their superb working properties, the use of watertube boilers is highly preferred in the following major areas:

  • Variety of process applications in industries
  • Chemical processing divisions
  • Pulp and Paper manufacturing plants
  • Refining units

Besides, they are frequently employed in power generation plants where large quantities of steam (ranging up to 500 kg/s) having high pressures i.e. approximately 16 megapascals (160 bar) and high temperatures reaching up to 550 °C are generally required. For example, the Ivanpah solar-power station uses two Rentech Type-D watertube boilers for plant warmup, and when operating as a fossil fueled power station.[4]

Stationary

Modern boilers for power generation are almost entirely water-tube designs, owing to their ability to operate at higher pressures. Where process steam is required for heating or as a chemical component, then there is still a small niche for fire-tube boilers. One notable exception is in typical Nuclear power stations (Pressurized Water Reactors), where the steam generators are generally configured similar to firetube boiler designs. In these applications the hot gas path through the "Firetubes" actually carries the very hot/high pressure primary coolant from the reactor, and steam is generated on the external surface of the tubes.

Marine

Their ability to work at higher pressures has led to marine boilers being almost entirely water-tube. This change began around 1900, and traced the adoption of turbines for propulsion rather than reciprocating (i.e. piston) engines – although watertube boilers were also used with reciprocating engines, and firetube boilers were also used in many marine turbine applications.

Railway

There has been no significant adoption of water-tube boilers for railway locomotives. A handful of experimental designs were produced, but none of these were successful or led to their widespread use.[5] Most water-tube railway locomotives, especially in Europe, used the Schmidt system. Most were compounds, and a few uniflows. The Norfolk and Western Railway's Jawn Henry was an exception, as it used a steam turbine combined with an electric transmission.[6]

Rebuilt completely after a fatal accident
Using a Yarrow boiler, rather than Schmidt. Not successful and re-boilered with a conventional boiler.[7]

Hybrids

A slightly more successful adoption was the use of hybrid water-tube / fire-tube systems. As the hottest part of a locomotive boiler is the firebox, it was an effective design to use a water-tube design here and a conventional fire-tube boiler as an economiser (i.e. pre-heater) in the usual position.

One famous example of this was the USA Baldwin 4-10-2 No. 60000, built in 1926. Operating as a compound at a boiler pressure of 2,400 kilopascals (350 psi) it covered over 160,000 kilometres (100,000 mi) successfully. After a year though, it became clear that any economies were overwhelmed by the extra costs and it was retired to a museum display at the Franklin Institute in Philadelphia, Pennsylvania.[8] A series of twelve experimental locomotives were constructed at the Baltimore and Ohio Railroad's Mt. Clare shops under the supervision of George H. Emerson, but none of them was replicated in any numbers.[9]

 
Brotan boiler

The only railway use of water-tube boilers in any numbers was the Brotan boiler, invented in Austria in 1902 by Johann Brotan and found in rare examples throughout Europe. Hungary, though, was a keen user and had around 1,000 of them. Like the Baldwin, this combined a water-tube firebox with a fire-tube barrel. The original characteristic of the Brotan was a long steam drum running above the main barrel, making it resemble a Flaman boiler in appearance.[10][11]

Road

While the traction engine was usually built using its locomotive boiler as its frame, other types of steam road vehicles such as lorries and cars have used a wide range of different boiler types. Road transport pioneers Goldsworthy Gurney and Walter Hancock both used water-tube boilers in their steam carriages around 1830.

Most undertype wagons used water-tube boilers. Many manufacturers used variants of the vertical cross-tube boiler, including Atkinson, Clayton, Garrett and Sentinel. Other types include the Clarkson 'thimble tube' and the Foden O-type wagon's pistol-shaped boiler.[12]

Steam fire-engine makers such as Merryweather usually used water-tube boilers for their rapid steam-raising capacity.

Many steam cars used water-tube boilers, and the Bolsover Express company even made a water-tube replacement for the Stanley Steamer fire-tube boiler.[13]

Design variations

D-type boiler

The 'D-type' is the most common type of small- to medium-sized boilers, similar to the one shown in the schematic diagram. It is used in both stationary and marine applications. It consists of a large steam drum vertically connected to a smaller water drum (a.k.a. "mud drum") via multiple steam-generating tubes. These drums and tubes as well as the oil-fired burner are enclosed by water-walls - additional water-filled tubes spaced close together so as to prevent gas flow between them. These water wall tubes are connected to both the steam and water drums, so that they act as a combination of preheaters and downcomers as well as decreasing heat loss to the boiler shell.

M-type boilers

The M-type boilers were used in many US World War II warships including hundreds of Fletcher-class destroyers. Three sets of tubes form the shape of an M, and create a separately fired superheater that allows better superheat temperature control. In addition to the mud drum shown on a D-type boiler, an M-type has a water-screen header and a waterwall header at the bottom of the two additional rows of vertical tubes and downcomers.

Low water content

The low water content boiler has a lower and upper header connected by watertubes that are directly impinged upon from the burner. This is a "furnace-less" boiler that can generate steam and react quickly to changes in load.

Babcock & Wilcox boiler

 
Babcock & Wilcox boiler

Designed by the American firm of Babcock & Wilcox, this type has a single drum, with feedwater drawn from the bottom of the drum into a header that supplies inclined water-tubes. The watertubes supply steam back into the top of the drum. Furnaces are located below the tubes and drum.

This type of boiler was used by the Royal Navy's Leander-class frigates and in United States Navy New Orleans-class cruisers.

Stirling boiler

Main article: Stirling boiler

The Stirling boiler has near-vertical, almost-straight watertubes that zig-zag between a number of steam and water drums. Usually there are three banks of tubes in a "four drum" layout, but certain applications use variations designed with a different number of drums and banks.

They are mainly used as stationary boilers, owing to their large size, although the large grate area does also encourage their ability to burn a wide range of fuels. Originally coal-fired in power stations, they also became widespread in industries that produced combustible waste and required process steam. Paper pulp mills could burn waste bark, sugar refineries their bagasse waste. It is a horizontal drum type of boiler.

Yarrow

Main article: Yarrow boiler
 
End-view of a Yarrow boiler

Named after its designers, the then Poplar-based Yarrow Shipbuilders, this type of three-drum boiler has three drums in a delta formation connected by watertubes. The drums are linked by straight watertubes, allowing easy tube-cleaning. This does, however, mean that the tubes enter the drums at varying angles, a more difficult joint to caulk. Outside the firebox, a pair of cold-leg pipes between each drum act as downcomers.[14]

Due to its three drums, the Yarrow boiler has a greater water capacity. Hence, this type is usually used in older marine boiler applications. Its compact size made it attractive for use in transportable power generation units during World War II. In order to make it transportable, the boiler and its auxiliary equipment (fuel oil heating, pumping units, fans etc.), turbines, and condensers were mounted on wagons to be transported by rail.

White-Forster

The White-Forster type is similar to the Yarrow, but with tubes that are gradually curved. This makes their entry into the drums perpendicular, thus simpler to make a reliable seal.[14]

Thornycroft

 
End-view of a Thornycroft boiler

Designed by the shipbuilder John I. Thornycroft & Company, the Thornycroft type features a single steam drum with two sets of watertubes either side of the furnace. These tubes, especially the central set, have sharp curves. Apart from obvious difficulties in cleaning them, this may also give rise to bending forces as the tubes warm up, tending to pull them loose from the tubeplate and creating a leak. There are two furnaces, venting into a common exhaust, giving the boiler a wide base tapering profile.[14]

Forced circulation boiler

In a forced circulation boiler, a pump is added to speed up the flow of water through the tubes.[15]

Other types

See also

References

  1. ^ (PDF). Archived from the original (PDF) on 2016-10-11. Retrieved 2013-11-21.{{cite web}}: CS1 maint: archived copy as title (link)
  2. ^ Marshall, Chapman Frederick (16 December 2014). A History of Railway Locomotives down to the End of the Year 1831. BoD – Books on Demand. ISBN 9783845712871 – via Google Books.
  3. ^ . Archived from the original on 2016-03-09. Retrieved 2014-06-15.
  4. ^ "eCRMS" (PDF). Docketpublic.energy.ca.gov. Retrieved 2018-09-24.
  5. ^ . Loco Locomotive gallery. Archived from the original on 2018-07-22. Retrieved 2010-09-14.
  6. ^ "The Jawn Henry". Trains Magazine. Retrieved 2008-10-28.
  7. ^ . Loco Locomotive gallery D&H 1402 James Archibald. Archived from the original on 2018-07-22. Retrieved 2010-09-14. The Delaware and Hudson E7 class of water tube boiler locomotives consisted of three examples 1400-1402
  8. ^ "Baldwin 60000". Loco Locomotive gallery.
  9. ^ See chapter on "Experimentals" in Sagle, Lawrence W. (1964). B&O Power. Staufer. p. 288 ff.
  10. ^ . Loco Locomotive gallery. Archived from the original on 2018-07-22. Retrieved 2010-09-14.
  11. ^ "Brotan".
  12. ^ Kelly, Maurice A. (1975). The Undertype Steam Road Waggon. Cambridge: Goose and Son. ISBN 0-900404-16-7.
  13. ^ Harris, Karl N. (1 June 1967). Model Boilers and Boilermaking (New ed.). Kings Langley: Model & Allied Publications. ISBN 978-0852423776. OCLC 821813643. OL 8281488M.
  14. ^ a b c Stokers' Manual (PDF) (1912 ed.). London: His Majesty's Stationery Office via Eyre & Spottiswoode. 1912 [1901]. ASIN B00IZEYVAS. OCLC 222437497. OL 18715300M. (PDF) from the original on 15 March 2021. Retrieved 28 June 2021 – via Friends of the Cerberus.
  15. ^ Newest on Process Equipments (2012-11-25). "Boilers circulation systems: natural circulation and forced circulation". Enggcyclopedia. Retrieved 2013-09-30.

External links

 
Wikimedia Commons has media related to Water-tube boilers.

March 27, 2023
water, tube, boiler, high, pressure, watertube, boiler, also, spelled, water, tube, water, tube, type, boiler, which, water, circulates, tubes, heated, externally, fire, fuel, burned, inside, furnace, creating, which, boils, water, steam, generating, tubes, sm. A high pressure watertube boiler 1 also spelled water tube and water tube is a type of boiler in which water circulates in tubes heated externally by the fire Fuel is burned inside the furnace creating hot gas which boils water in the steam generating tubes In smaller boilers additional generating tubes are separate in the furnace while larger utility boilers rely on the water filled tubes that make up the walls of the furnace to generate steam Schematic diagram of a marine type watertube boiler The heated water steam mixture then rises into the steam drum Here saturated steam is drawn off the top of the drum In some services the steam passes through tubes in the hot gas path a superheater to become superheated Superheated steam is defined as steam that is heated above the boiling point at a given pressure Superheated steam is a dry gas and therefore is typically used to drive turbines since water droplets can severely damage turbine blades Saturated water at the bottom of the steam drum returns to the lower drum via large bore downcomer tubes where it pre heats the feedwater supply In large utility boilers the feedwater is supplied to the steam drum and the downcomers supply water to the bottom of the waterwalls To increase economy of the boiler exhaust gases are also used to pre heat combustion air blown into the burners and to warm the feedwater supply in an economizer Such watertube boilers in thermal power stations are also called steam generating units The older fire tube boiler design in which the water surrounds the heat source and gases from combustion pass through tubes within the water space is typically a much weaker structure and is rarely used for pressures above 2 4 MPa 350 psi A significant advantage of the watertube boiler is that there is less chance of a catastrophic failure there is not a large volume of water in the boiler nor are there large mechanical elements subject to failure A water tube boiler was patented by Blakey of England in 1766 and was made by Dallery of France in 1780 2 Contents 1 Applications 1 1 Stationary 1 2 Marine 1 3 Railway 1 3 1 Hybrids 1 4 Road 2 Design variations 2 1 D type boiler 2 2 M type boilers 2 3 Low water content 2 4 Babcock amp Wilcox boiler 2 5 Stirling boiler 2 6 Yarrow 2 7 White Forster 2 8 Thornycroft 2 9 Forced circulation boiler 2 10 Other types 3 See also 4 References 5 External linksApplications Edit The ability of watertube boilers to be designed without the use of excessively large and thick walled pressure vessels makes these boilers particularly attractive in applications that require dry high pressure high energy steam including steam turbine power generation 3 Owing to their superb working properties the use of watertube boilers is highly preferred in the following major areas Variety of process applications in industries Chemical processing divisions Pulp and Paper manufacturing plants Refining unitsBesides they are frequently employed in power generation plants where large quantities of steam ranging up to 500 kg s having high pressures i e approximately 16 megapascals 160 bar and high temperatures reaching up to 550 C are generally required For example the Ivanpah solar power station uses two Rentech Type D watertube boilers for plant warmup and when operating as a fossil fueled power station 4 Stationary Edit Modern boilers for power generation are almost entirely water tube designs owing to their ability to operate at higher pressures Where process steam is required for heating or as a chemical component then there is still a small niche for fire tube boilers One notable exception is in typical Nuclear power stations Pressurized Water Reactors where the steam generators are generally configured similar to firetube boiler designs In these applications the hot gas path through the Firetubes actually carries the very hot high pressure primary coolant from the reactor and steam is generated on the external surface of the tubes Marine Edit Their ability to work at higher pressures has led to marine boilers being almost entirely water tube This change began around 1900 and traced the adoption of turbines for propulsion rather than reciprocating i e piston engines although watertube boilers were also used with reciprocating engines and firetube boilers were also used in many marine turbine applications Railway Edit There has been no significant adoption of water tube boilers for railway locomotives A handful of experimental designs were produced but none of these were successful or led to their widespread use 5 Most water tube railway locomotives especially in Europe used the Schmidt system Most were compounds and a few uniflows The Norfolk and Western Railway s Jawn Henry was an exception as it used a steam turbine combined with an electric transmission 6 LMS 6399 FuryRebuilt completely after a fatal accidentLNER 10000 Hush hush Using a Yarrow boiler rather than Schmidt Not successful and re boilered with a conventional boiler 7 Hybrids Edit A slightly more successful adoption was the use of hybrid water tube fire tube systems As the hottest part of a locomotive boiler is the firebox it was an effective design to use a water tube design here and a conventional fire tube boiler as an economiser i e pre heater in the usual position One famous example of this was the USA Baldwin 4 10 2 No 60000 built in 1926 Operating as a compound at a boiler pressure of 2 400 kilopascals 350 psi it covered over 160 000 kilometres 100 000 mi successfully After a year though it became clear that any economies were overwhelmed by the extra costs and it was retired to a museum display at the Franklin Institute in Philadelphia Pennsylvania 8 A series of twelve experimental locomotives were constructed at the Baltimore and Ohio Railroad s Mt Clare shops under the supervision of George H Emerson but none of them was replicated in any numbers 9 Brotan boiler The only railway use of water tube boilers in any numbers was the Brotan boiler invented in Austria in 1902 by Johann Brotan and found in rare examples throughout Europe Hungary though was a keen user and had around 1 000 of them Like the Baldwin this combined a water tube firebox with a fire tube barrel The original characteristic of the Brotan was a long steam drum running above the main barrel making it resemble a Flaman boiler in appearance 10 11 Road Edit While the traction engine was usually built using its locomotive boiler as its frame other types of steam road vehicles such as lorries and cars have used a wide range of different boiler types Road transport pioneers Goldsworthy Gurney and Walter Hancock both used water tube boilers in their steam carriages around 1830 Most undertype wagons used water tube boilers Many manufacturers used variants of the vertical cross tube boiler including Atkinson Clayton Garrett and Sentinel Other types include the Clarkson thimble tube and the Foden O type wagon s pistol shaped boiler 12 Steam fire engine makers such as Merryweather usually used water tube boilers for their rapid steam raising capacity Many steam cars used water tube boilers and the Bolsover Express company even made a water tube replacement for the Stanley Steamer fire tube boiler 13 Design variations EditThis section needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Water tube boiler news newspapers books scholar JSTOR October 2020 Learn how and when to remove this template message D type boiler Edit The D type is the most common type of small to medium sized boilers similar to the one shown in the schematic diagram It is used in both stationary and marine applications It consists of a large steam drum vertically connected to a smaller water drum a k a mud drum via multiple steam generating tubes These drums and tubes as well as the oil fired burner are enclosed by water walls additional water filled tubes spaced close together so as to prevent gas flow between them These water wall tubes are connected to both the steam and water drums so that they act as a combination of preheaters and downcomers as well as decreasing heat loss to the boiler shell M type boilers Edit The M type boilers were used in many US World War II warships including hundreds of Fletcher class destroyers Three sets of tubes form the shape of an M and create a separately fired superheater that allows better superheat temperature control In addition to the mud drum shown on a D type boiler an M type has a water screen header and a waterwall header at the bottom of the two additional rows of vertical tubes and downcomers Low water content Edit The low water content boiler has a lower and upper header connected by watertubes that are directly impinged upon from the burner This is a furnace less boiler that can generate steam and react quickly to changes in load Babcock amp Wilcox boiler Edit Babcock amp Wilcox boiler Designed by the American firm of Babcock amp Wilcox this type has a single drum with feedwater drawn from the bottom of the drum into a header that supplies inclined water tubes The watertubes supply steam back into the top of the drum Furnaces are located below the tubes and drum This type of boiler was used by the Royal Navy s Leander class frigates and in United States Navy New Orleans class cruisers Stirling boiler Edit Main article Stirling boiler The Stirling boiler has near vertical almost straight watertubes that zig zag between a number of steam and water drums Usually there are three banks of tubes in a four drum layout but certain applications use variations designed with a different number of drums and banks They are mainly used as stationary boilers owing to their large size although the large grate area does also encourage their ability to burn a wide range of fuels Originally coal fired in power stations they also became widespread in industries that produced combustible waste and required process steam Paper pulp mills could burn waste bark sugar refineries their bagasse waste It is a horizontal drum type of boiler Yarrow Edit Main article Yarrow boiler End view of a Yarrow boiler Named after its designers the then Poplar based Yarrow Shipbuilders this type of three drum boiler has three drums in a delta formation connected by watertubes The drums are linked by straight watertubes allowing easy tube cleaning This does however mean that the tubes enter the drums at varying angles a more difficult joint to caulk Outside the firebox a pair of cold leg pipes between each drum act as downcomers 14 Due to its three drums the Yarrow boiler has a greater water capacity Hence this type is usually used in older marine boiler applications Its compact size made it attractive for use in transportable power generation units during World War II In order to make it transportable the boiler and its auxiliary equipment fuel oil heating pumping units fans etc turbines and condensers were mounted on wagons to be transported by rail White Forster Edit The White Forster type is similar to the Yarrow but with tubes that are gradually curved This makes their entry into the drums perpendicular thus simpler to make a reliable seal 14 Thornycroft Edit End view of a Thornycroft boiler Designed by the shipbuilder John I Thornycroft amp Company the Thornycroft type features a single steam drum with two sets of watertubes either side of the furnace These tubes especially the central set have sharp curves Apart from obvious difficulties in cleaning them this may also give rise to bending forces as the tubes warm up tending to pull them loose from the tubeplate and creating a leak There are two furnaces venting into a common exhaust giving the boiler a wide base tapering profile 14 Forced circulation boiler Edit In a forced circulation boiler a pump is added to speed up the flow of water through the tubes 15 Other types Edit O type boiler A type boiler Flex tube boiler M type control superheaterSee also EditThree drum boiler Clarkson thimble tube boiler Corner tube boiler Internally rifled boiler tubes also known as serve tubes References Edit Archived copy PDF Archived from the original PDF on 2016 10 11 Retrieved 2013 11 21 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Marshall Chapman Frederick 16 December 2014 A History of Railway Locomotives down to the End of the Year 1831 BoD Books on Demand ISBN 9783845712871 via Google Books Boiler Efficiency Water Tube Boilers Archived from the original on 2016 03 09 Retrieved 2014 06 15 eCRMS PDF Docketpublic energy ca gov Retrieved 2018 09 24 High Pressure Steam Locomotive Technology Loco Locomotive gallery Archived from the original on 2018 07 22 Retrieved 2010 09 14 The Jawn Henry Trains Magazine Retrieved 2008 10 28 LNER 10000 High Pressure Locomotive Loco Locomotive gallery D amp H 1402 James Archibald Archived from the original on 2018 07 22 Retrieved 2010 09 14 The Delaware and Hudson E7 class of water tube boiler locomotives consisted of three examples 1400 1402 Baldwin 60000 Loco Locomotive gallery See chapter on Experimentals in Sagle Lawrence W 1964 B amp O Power Staufer p 288 ff Brotan Loco Locomotive gallery Archived from the original on 2018 07 22 Retrieved 2010 09 14 Brotan Kelly Maurice A 1975 The Undertype Steam Road Waggon Cambridge Goose and Son ISBN 0 900404 16 7 Harris Karl N 1 June 1967 Model Boilers and Boilermaking New ed Kings Langley Model amp Allied Publications ISBN 978 0852423776 OCLC 821813643 OL 8281488M a b c Stokers Manual PDF 1912 ed London His Majesty s Stationery Office via Eyre amp Spottiswoode 1912 1901 ASIN B00IZEYVAS OCLC 222437497 OL 18715300M Archived PDF from the original on 15 March 2021 Retrieved 28 June 2021 via Friends of the Cerberus Newest on Process Equipments 2012 11 25 Boilers circulation systems natural circulation and forced circulation Enggcyclopedia Retrieved 2013 09 30 External links Edit Wikimedia Commons has media related to Water tube boilers Robertson Leslie Stephen 10 October 2018 1901 Water Tube Boilers Based on a Short Course of Lectures Delivered at University College London New York D Van Nostrand Company ISBN 978 0342103232 OCLC 556436534 OL 32303266M Retrieved 28 June 2021 via Internet Archive Retrieved from https en wikipedia org w index php title Water tube boiler amp oldid 1144458912, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.