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Metallurgical furnace

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Industrial furnace from 1907.

A metallurgical furnace, often simply referred to as a furnace when the context is known, is an industrial furnace used to heat, melt, or otherwise process metals. Furnaces have been a central piece of equipment throughout the history of metallurgy; processing metals with heat is even its own engineering specialty known as pyrometallurgy.

One important furnace application, especially in iron and steel production, is smelting, where metal ores are reduced under high heat to separate the metal content from mineral gangue. The heat energy to fuel a furnace may be supplied directly by fuel combustion or by electricity. Different processes and the unique properties of specific metals and ores have led to many different furnace types.[1]

Air blast furnaces

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The Manufacture of Iron -- Filling the Furnace, an 1873 wood engraving

Many furnace designs for smelting combine ore, fuel, and other reagents like flux in a single chamber. Mechanisms, such as bellows or motorized fans, then drive pressurized blasts of air into the chamber. These blasts make the fuel burn hotter and drive chemical reactions.

Furnaces of this type include:

Blowing in

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Even smaller, pre-industrial bloomeries possess significant thermal mass. Raising a cold furnace to the necessary temperature for smelting iron requires a significant amount of energy, regardless of modern technology. For this reason, metallurgists will try their best to keep blast furnaces running continuously, and shutting down a furnace is seen as an unfortunate event.

Conversely, starting up a new furnace, or one that had been temporarily shut down, is often a special occasion. In traditional bloomeries, several rounds of fuel would need to be burnt away before the furnace was ready to accept a charge of ore. In English, this process became known as "blowing in" the furnace, while a furnace that had to be shut down and went cold had been "blown out", terms that are still applied to contemporary blast furnaces.[2]

Reverberatory furnaces

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A reverberatory furnace still exposes the reaction chamber, where metal or ore is combined with reagents, to a stream of exhaust gases. However, no fuel is directly added to the chamber, and combustion occurs in a separate chamber. Furnaces of this type include:

Refining converters

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In metallurgy, furnaces used to refine metals further, particularly iron into steel, are also often called converters:

Electric furnaces

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Modern TLS furnace used in copper smelting during heat up.
Modern TLS furnace used in copper smelting during heat up.

Just as other industries have trended towards electrification, electric furnaces have become prevalent in metallurgy. However, while any furnace can theoretically use an electrical heating element, process specifics mostly limit this approach to furnaces with lower power demands.

Instead, electric metallurgical furnaces often apply an electric current directly to batches of metal. This is particularly useful for recycling (still relatively pure) scrap metal, or remelting ingots for casting in foundries. The absence of any fuel or exhaust gases also makes these designs versatile for heating all kinds of metals.[a] Such designs include:

Other furnaces

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Other metallurgical furnaces have special design features or uses. One function is heating material short of melting, in order to perform heat treatment or hot working. Basic furnaces used this way include:

Another class of furnaces isolate the material from the surrounding atmosphere and contaminants, enabling advanced heat treatments and other techniques:

  • Muffle furnaces enclose the material to keep out contaminants and divert any exhaust away from the area
  • Autoclaves are reinforced, seal airtight, and can expose material to heat and elevated pressure
  • Vacuum furnaces are similar to autoclaves, but expose the material to a vacuum instead

Notes

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  1. ^ The absence of any additional chemistry is not always an advantage though. For example, smelting iron is still mostly done with blast furnaces, partly because the carbon monoxide created by burning coke is also excellent for chemically reducing the iron.

References

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  1. ^ D, C. H. (1923-11-24). "Metallurgical Furnaces". Nature. 112 (2821): 755–756. doi:10.1038/112755a0. ISSN 1476-4687. S2CID 28751324.
  2. ^ Eggert, Gerald (15 January 2008). "How to "Blow In" a Newly Built or a Cold Iron Furnace". Medieval Studies. Medieval Technology and American History. One-Minute Essays. Penn State University. Archived from the original on 26 September 2023. Retrieved 18 February 2024.