Aeolipile

An aeolipile (or aeolipyle, or eolipile), also known as a Hero's engine, is a simple, bladeless radial steam turbine which spins when the central water container is heated. Torque is produced by steam jets exiting the turbine, much like a tip jet[1] or rocket engine.[2] In the 1st century AD, Hero of Alexandria described the device in Roman Egypt, and many sources give him the credit for its invention.[3][4]

An illustration of Hero's aeolipile

The aeolipile which Hero described is considered to be the first recorded steam engine or reaction steam turbine.[5] The name – derived from the Greek word Αἴολος and Latin word pila – translates to "the ball of Aeolus", Aeolus being the Greek god of the air and wind.

Predating Hero's writings, a device called an aeolipile was described in the 1st century BC by Vitruvius in his treatise De architectura; however, it is unclear if it is the same device or a predecessor, as he does not mention rotating parts.[6]

Description and physics

A classroom model of an aeolipile

The aeolipile consists of a vessel, usually a "simple" solid of revolution, such as a sphere or a cylinder, arranged to rotate on its axis, having oppositely bent or curved nozzles projecting from it (tipjets). When the vessel is pressurised with steam, steam is expelled through the nozzles, which generates thrust due to the rocket principle[7] as a consequence of the 2nd and 3rd of Newton's laws of motion. When the nozzles, pointing in different directions, produce forces along different lines of action perpendicular to the axis of the bearings, the thrusts combine to result in a rotational moment (mechanical couple), or torque, causing the vessel to spin about its axis. Aerodynamic drag and frictional forces in the bearings build up quickly with increasing rotational speed (rpm) and consume the accelerating torque, eventually cancelling it and achieving a steady state speed.

Typically, and as Hero described the device, the water is heated in a simple boiler which forms part of a stand for the rotating vessel. Where this is the case, the boiler is connected to the rotating chamber by a pair of pipes that also serve as the pivots for the chamber. Alternatively the rotating chamber may itself serve as the boiler, and this arrangement greatly simplifies the pivot/bearing arrangements, as they then do not need to pass steam. This can be seen in the illustration of a classroom model shown here.

History

Illustration from Hero's Pneumatica

Both Hero and Vitruvius draw on the much earlier work by Ctesibius (285–222 BCE), also known as Ktesibios or Tesibius, who was an inventor and mathematician in Alexandria, Ptolemaic Egypt. He wrote the first treatises on the science of compressed air and its uses in pumps.

Vitruvius's description

Vitruvius (c. 80 BCE – c. 15 CE) mentions aeolipiles by name:

Aeolipilae are hollow brazen vessels, which have an opening or mouth of small size, by means of which they can be filled with water. Prior to the water being heated over the fire, but little wind is emitted. As soon, however, as the water begins to boil, a violent wind issues forth.[6]

Hero's description

Hero (c. 10–70 CE) takes a more practical approach, in that he gives instructions how to make one:

No. 50. The Steam-Engine. PLACE a cauldron over a fire: a ball shall revolve on a pivot. A fire is ignited under a cauldron, A B, (fig. 50), containing water, and covered at the mouth by the lid C D; with this the bent tube E F G communicates, the extremity of the tube being fitted into a hollow ball, H K. Opposite to the extremity G place a pivot, L M, resting on the lid C D; and let the ball contain two bent pipes, communicating with it at the opposite extremities of a diameter, and bent in opposite directions, the bends being at right angles and across the lines F G, L M. As the cauldron gets hot it will be found that the steam, entering the ball through E F G, passes out through the bent tubes towards the lid, and causes the ball to revolve, as in the case of the dancing figures.[3]

Practical usage

A modern replica of Hero's aeolipile.

It is not known whether the aeolipile was put to any practical use in ancient times, and if it was seen as a pragmatic device, a whimsical novelty, an object of reverence, or some other thing. A source described it as a mere curiosity for the ancient Greeks, or a "party trick".[8] Hero's drawing shows a standalone device, and was presumably intended as a "temple wonder", like many of the other devices described in Pneumatica.[3]

Vitruvius, on the other hand, mentions use of the aeolipile for demonstrating the physical properties of the weather. He describes the aeolipile as

a scientific invention [to] discover a divine truth lurking in the laws of the heavens.[6]

After describing the device's construction (see above) he concludes:

Thus from this slight and very short experiment we may understand and judge the mighty and wonderful laws of the heavens and the nature of winds.[6]

In 1543, Blasco de Garay, a scientist and a captain in the Spanish navy, allegedly demonstrated before the Holy Roman Emperor, Charles V and a committee of high officials an invention he claimed could propel large ships in the absence of wind using an apparatus consisted of copper boiler and moving wheels on either side of the ship.[9] This account was preserved by the royal Spanish archives at Simancas.[10] It is proposed that de Garay used Hero's aeolipile and combined it with the technology used in Roman boats and late medieval galleys.[9] Here, de Garay's invention introduced an innovation where the aeolipile had practical usage, which was to generate motion to the paddlewheels, demonstrating the feasibility of steam-driven boats.[10] This claim was denied by Spanish authorities.[11]

See also

References

  1. jet engine
  2. NASA Glenn Learning Technologies Project (LTP)
  3. Hero (1851), "Section 50 – The Steam Engine", The Pneumatics of Hero of Alexandria, translated by Bennet Woodcroft, London: Taylor Walton and Maberly, Bibcode:1851phal.book.....W, archived from the original on 11 February 2012 via University of Rochester
  4. Hero (1899). "Pneumatika, Book II, Chapter XI". Herons von Alexandria Druckwerke und Automatentheater (in Greek and German). Wilhelm Schmidt (translator). Leipzig: B.G. Teubner. pp. 228–232.
  5. "turbine." Encyclopædia Britannica. 2007. Encyclopædia Britannica Online. 18 July 2007 <http://www.britannica.com/eb/article-45691>.
  6. "De Architectura", Chapter VI (paragraph 2) from Ten Books on Architecture by Vitruvius (1st century BC), published 17 June 2008 accessed 2009-07-07
  7. Aeolipile
  8. Gruntman, Mike (2004). Blazing the Trail: The Early History of Spacecraft and Rocketry. Reston, VA: American Institute of Aeronautics and Astronautics, Inc. p. 1. ISBN 156347705X.
  9. Kitsikopoulos, Harry (2015). Innovation and Technological Diffusion: An economic history of early steam engines. Oxon: Routledge. p. 5. ISBN 9781138948112.
  10. Stone, Joe (2015). Floating Palaces of the Great Lakes: A History of Passenger Steamships on the Inland Seas. Ann Arbor: University of Michigan Press. p. 9. ISBN 9780472071753.
  11. Museo Naval, Catálogo guia del Museo Naval de Madrid, IX edición, Madrid, 1945, page 128.

Further reading

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