The cementation process is an

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technology for making

steel Steel is an alloy made up of iron with added carbon to improve its strength and fracture resistance compared to other forms of iron. Many other elements may be present or added. Stainless steels that are corrosion- and oxidation-resistant ty ...

carburization Carburising, carburizing (chiefly American English), or carburisation is a heat treatment process in which iron or steel absorbs carbon while the metal is heated in the presence of a carbon-bearing material, such as charcoal or carbon monoxide. ...

of iron. Unlike modern steelmaking, it increased the amount of carbon in the iron. It was apparently developed before the 17th century.

Derwentcote Steel Furnace Derwentcote Steel Furnace (), Rowlands Gill, near Newcastle upon Tyne, England, built in 1720, is an example of an early Cementation process, cementation furnace which produced high-grade steel. A Grade I listed building, it is part of an indust ...

, built in 1720, is the earliest surviving example of a cementation furnace. Another example in the UK is the cementation furnace in Doncaster Street, Sheffield.

Origins

The process was described in a treatise published in Prague in 1574. It was again invented by Johann Nussbaum of Magdeburg, who began operations at Nuremberg (with partners) in 1601. The process was patented in England by William Ellyot and Mathias Meysey in 1614. At that date, the "invention" could consist merely of the introduction of a new industry or product, or even a mere monopoly. They evidently soon transferred the patent to Sir Basil Brooke, but he was forced to surrender it in 1619. A clause in the patent prohibiting the import of

was found to be undesirable because he could not supply as much good steel as was needed.P. W. King, 'The Cartel in Oregrounds Iron: trading in the raw material for steel during the eighteenth century' ''Journal of Industrial History'' 6(1) (2003), 25-49. Brooke's furnaces were probably in his manor of Madeley at Coalbrookdale (which certainly existed before the English Civil War) where two cementation furnaces have been excavated. He probably used bar iron from the Forest of Dean, where he was a partner in farming the King's ironworks in two periods. By 1631, it was recognised that Swedish iron was the best raw material and then or later particularly certain marks (brands) such as ''double bullet'' (so called from the mark OO) from

Österby Österby is a village in Lääne-Nigula Parish, Lääne County, in western Estonia Estonia, formally the Republic of Estonia, is a country by the Baltic Sea in Northern Europe. It is bordered to the north by the Gulf of Finland acros ...

and ''hoop L'' from Leufsta (now Lövsta), whose mark consisted of an L in a circle, both belonging to Louis De Geer and his descendants. These were among the first ironworks in

Sweden Sweden, formally the Kingdom of Sweden,The United Nations Group of Experts on Geographical Names states that the country's formal name is the Kingdom of SwedenUNGEGN World Geographical Names, Sweden./ref> is a Nordic country located on ...

to use the Walloon process of fining iron, producing what was known in England as oregrounds iron. It was so called from the Swedish port of Öregrund, north of Stockholm, in whose hinterland most of the ironworks lay. The ore used came ultimately from the Dannemora mine.

Process

The process begins with wrought iron and

charcoal Charcoal is a lightweight black carbon residue produced by strongly heating wood (or other animal and plant materials) in minimal oxygen to remove all water and volatile constituents. In the traditional version of this pyrolysis process, cal ...

. It uses one or more long stone ''pots'' inside a furnace. Typically, in Sheffield, each pot was 14 feet by 4 feet and 3.5 feet deep. Iron bars and charcoal are packed in alternating layers, with a top layer of charcoal and then refractory matter to make the pot or "coffin" airtight. Some manufacturers used a mixture of powdered charcoal, soot and mineral salts, called ''cement powder''. In larger works, up to 16 tons of iron were treated in each cycle, though it can be done on a small scale, such as in a small furnace or blacksmith's forge. Depending on the thickness of the iron bars, the pots were then heated from below for a week or more. Bars were regularly examined and when the correct condition was reached the heat was withdrawn and the pots were left until cool—usually around fourteen days. The iron had gained a little over 1% in mass from the carbon in the charcoal, and had become heterogeneous bars of ''blister steel''. The bars were then shortened, bound, heated and forge welded together to become ''shear steel''. It would be cut and re welded multiple times, with each new weld producing a more homogeneous, higher quality steel. This would be done at most 3-4 times, as more is unnecessary and could potentially cause carbon loss from the steel. Alternatively they could be broken up and melted in a crucible using a crucible furnace with a

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to become '' crucible steel'' (at the time also called ''cast steel''), a process devised by Benjamin Huntsman in Sheffield in the 1740s.

Similar processes

Brass production

In the early modern period, brass, an alloy of copper and zinc, was usually produced by a cementation process in which metallic copper was heated with calamine, a zinc ore, to make calamine brass.

Notes

References

* K. C. Barraclough, ''Steel before Bessemer I: Blister Steel: The Birth of an Industry'' (1985). * K. C. Barraclough, "Swedish Iron and Sheffield Steel", ''History of Technology'' 12 (1990), 1–39. * Dorian Gerhold, "The steel industry in England, 1614-1740", in R.W. Hoyle (ed.), "Histories of people and landscape: essays on the Sheffield region in memory of David Hey" (2021), 65-86 * P. W. King, "The Cartel in Oregrounds Iron", ''Journal of Industrial History'' 6 (2003), 25–48. * R. J. MacKenzie and J. A Whiteman, "Why pay more? An archaeometallurgical examination of 19th century Swedish Wrought iron and Sheffield blister steel", ''Historical Metallurgy'' 40(2) (2006), 138–49. {{Iron and steel production Steelmaking Metallurgical processes Obsolete technologies