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Trompe

From Wikipedia, the free encyclopedia
A Catalan forge trompe

A trompe is a water-powered air compressor, commonly used before the advent of the electric-powered compressor. A trompe is somewhat like an airlift pump working in reverse.

Trompes were used to provide compressed air for bloomery furnaces in Catalonia[1] and the USA.[2] The presence of a trompe is a signature attribute of a Catalan forge, a type of bloomery furnace.

Trompes can be enormous. At Canadian Hydro Developers' Ragged Chute facility in New Liskeard, Ontario, water falls down a shaft 351 feet (107 m) deep and 9 ft (2.7 m) across to generate compressed air for mining equipment and ventilation.[3]

Operation

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Trompes are very simple devices. They consist of four main parts: a water-supply pipe or shaft with an air-inlet inside it, a water outflow pipe, a separation chamber, and a takeoff air-pipe. The vertical pipe or shaft goes down from higher point to a separation chamber; a pipe, that is typically narrower than previous one, coming away from that chamber, allows the water to exit at a lower level, and another pipe (air-pipe) coming from the chamber allows the compressed air to exit as needed.

Sketch of a hydraulic trompe with the name of its different constituent elements.

Water rushing down the vertical pipe falls through a constriction. The constriction produces a lower pressure because of the venturi effect, and an external port allows air to be sucked in thus creating a constant air supply. The air forms bubbles in the pipe. As the bubbles go down the pipe they are pressurized proportionally to the hydraulic head, which is the height of the column of water in the pipe. The compressed air rises to the top of the separation chamber (wind box). The separation chamber has a compressed-air takeoff pipe, and the compressed air can be used as a power source.

The energy of the falling water creates a partial vacuum inside the pipe that is compensated by the air from the outside atmosphere provided through inlet. The air is compressed by surrounding water pressure (which increases under a column due to the discharge to atmospheric pressure). The pressure of the air delivered cannot exceed the hydraulic head of the discharge pipe of the separation chamber.[4]

Large trompes were often situated at high waterfalls so that ample head was available. (However, trompes can raise the water, via siphon-effect, nearly to 70% of its initial elevation.) The Ragged Chute plant on the Montreal River near the town of Cobalt, Ontario, is a trompe and tourist attraction. It is now owned by TransAlta (formerly by Canadian Hydro Developers) and exists beside a modern hydroelectric plant.[3]

Compressed air from a trompe is at the temperature of the water, and its partial pressure of water vapor is that of the dewpoint of the water's temperature. If the water is cool, the compressed air can be made very dry by passing it through pipes that are warmer than the water. Often, ordinary outside air can warm the pipes enough to produce dry, cool compressed air.

Today, trompes constructed of plastic pipe are being used to provide aeration for mine drainage treatment. In this application, mine water is used to drive the trompe and the compressed air that is generated is used to oxygenate the mine water and to drive off excess dissolved carbon dioxide that may be present thus raising the pH of the water being treated.[5]

The trompe is closely related to the Sprengel vacuum pump which uses mercury falling through a tube to create a vacuum instead of pressure.

Principle of a Taylor hydraulic trompe.

See also

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References

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  1. ^ The Catalan process for the direct production of malleable iron and its spread to Europe and the Americas PDF by Estanislau Tomàs (retrieved March 23, 2010)
  2. ^ Bond, A. Russel (1939). The Story of Mechanics. New York: P. F. Collier & Son Corporation. pp. 90–93.
  3. ^ a b Ragged Chutes Archived 2011-03-24 at the Wayback Machine
  4. ^ IMechE (Institution of Mechanical Engineers),Hydropower Developments: New Projects, Rehabilitation, and Power Recovery, John Wiley & Sons, 2005 ISBN 1860584799, p.42
  5. ^ Leavitt, Bruce R. (2011); Aeration of Mine Water Using a TROMPE; 2011 West Virginia Surface Mine Drainage Task Force Symposium (past symposium papers/2011 symposium papers/ at wvmdtaskforce.com)
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