Ljungström turbine

The Ljungström turbine (Ljungströmturbinen) is a steam turbine. It is also known as the STAL turbine, from the company name STAL (Swedish: Svenska Turbinfabriks Aktiebolaget Ljungström). The technology has had numerous uses since its conception, from power plants to vehicles as large as the supertanker Seawise Giant.^[1]

The turbine was invented circa 1908 by the Swedish brothers Birger Ljungström (1872–1948) and Fredrik Ljungström (1875–1964). The Ljungström brothers were creative, versatile inventors, typical of the 19th century. They not only named the turbine type, but also an early form of a bicycle.^[2]^[3]^[4]

Functionality

The steam flows through the machine in a radial direction from the centre to the outer extremities. The turbine consists of two halves that rotate against each other. As a result, each rotor blade of the one turbine half serves simultaneously as the guide blade of the other half. The different direction of rotation of the two halves is either compensated by a gearbox connected downstream or by separate generators if the turbine is used for the generation of electrical power. The Ljungström turbine can either be used with a condenser to recover the exhaust steam as condensate, or alternatively the exhaust can be utilised for the supply of a district heating grid, and thus the turbine is flexible in its application. It was therefore used in large industrial complexes, which could use the exhaust of this engine for both combined heat and power as well as its electric energy. The functionality has been employed for several power plants.^[5]^[6]

In principle, the maximum power possible is about 32 MW, since the diameter of the two turbine halves are limited to a practical size due to fabrication constraints. Coupled with a Parsons turbine, the output of a Ljungström turbine can be increased to about 50 MW. Since more modern steam power plants have a significantly higher performance, the Ljungström turbine is generally no longer utilised today. The largest ship ever built, the ULCC supertanker Seawise Giant, was powered by this type of engine.^[7]

Gallery

Radial impeller for Ljungstrom turbine - Museo scienza tecnologia, Milan
Factory in Gåshaga, Lidingö, Stockholm, for production of Ljungström locomotives, (1918)
Ljungström 50 MW electric generator unit for power station in Västerås (1932)
Turbine rotor of the same turbine (50 MW)
STAL counterpressure steam turbine of steel
Rotor for a Ljungström turbine with internal radial and external axial blading

References

^ "Ljungstrom Turbine". gracesguide.co.uk. UK: Grace's Guide Ltd.
^ "Birger Ljungström". Svenskt biografiskt lexikon. Retrieved March 1, 2020.
^ "Ljungströmturbinen". Tekniska museet. Retrieved March 1, 2020.
^ "Fredrik Ljungström". Svenskt biografiskt lexikon. Retrieved March 1, 2020.
^ "Swedish steam turbine technology" (PDF). Lund University / LTH / Energy Sciences / TPE / Magnus Genrup. Retrieved March 1, 2020.
^ "Svenska Turbinfabriks Ab Ljungström". tekniskamuseet. Archived from the original on September 9, 2016. Retrieved March 1, 2020.
^ "Seawise Giant". relevantsearchscotland.co.uk. Retrieved March 1, 2020.

Bibliography

Sigvard Strandh: Die Maschine: Geschichte, Elemente, Funktion. Ein enzyklopädisches Sachbuch", Herder Verlag, 1980. ISBN 3-451-18873-2 (Ljungströmturbine, pp. 133–135, Svea-Bike, p. 220 and Fig. 221)

External links

Wikimedia Commons has media related to Ljungström turbines.

Ljungströmturbine Tekniskamuseet
Swedish innovations Swedish Institute
STAL-turbin till Tekniska Museet by Carl-Göran Nilson
Science Museum Group: Brush Ljungstrom radial-flow steam turbine
Science Industry Museum: "Balance of power: The exceptional case of the Brush Ljungström Turbine"
BRUSH electrical history – a collection

Steam engines

Operating cycle

Valves

Valves	Slide D slide Piston Drop Corliss Poppet Sleeve Bash
Valve gear	Gab Stephenson link Joy Walschaerts Allan Baker Corliss Lentz Caprotti Gresley conjugated Southern

Mechanisms

Beam
Cataract
Centrifugal governor
Connecting rod
Crank
Crankshaft
Tusi couple hypocycloidal straight line mechanism
Link chain
Parallel motion
Plate chain
Rotative beam
Sun and planet gear
Watt's linkage

Boilers

Simple boilers	Haystack Wagon Egg-ended Box Flued Cornish Lancashire
Fire-tube boilers	Locomotive Scotch Launch
Water-tube boilers	Babcock & Wilcox Field-tube Sentinel Stirling Thimble tube Three-drum Yarrow
Boiler feed	Feedwater heater Feedwater pump Injector

Cylinder

Condenser

Other

History

Precursors

Savery Engine (1698)

Newcomen engine

Watt engine

Beam	Kinneil Engine (1768) Old Bess (1777) Chacewater Mine engine (1778) Smethwick Engine (1779) Resolution (1781)
Rotative beam	Soho Manufactory engine (1782) Bradley Works engine (1783) Whitbread Engine (1785) National Museum of Scotland engine (1786) Lap Engine (1788)