Vitreous enamel

Detail of painted enamel dish, Limoges, mid-16th century, attributed to Jean de Court, Waddesdon Bequest
The murder of Thomas Becket, detail from a reliquary in champlevé enamel, Limoges

Vitreous enamel, also called porcelain enamel, is a material made by fusing powdered glass to a substrate by firing, usually between 750 and 850 °C (1,380 and 1,560 °F). The powder melts, flows, and then hardens to a smooth, durable vitreous coating on metal, or on glass or ceramics.

The term "enamel" is most often restricted to work on metal, which is the subject of this article. Enamelled glass is also called "painted". Fired enamelware is an integrated layered composite of glass and metal.

The word enamel comes from the Old High German word smelzan (to smelt) via the Old French esmail,[1] or from a Latin word smaltum, first found in a 9th-century life of Leo IV.[2] Used as a noun, "an enamel" is usually a small decorative object coated with enamel.

Enamelling is an old and widely adopted technology, for most of its history mainly used in jewelry and decorative art.

Since the 19th century the term applies also to industrial materials and many metal consumer objects, such as some cooking vessels, dishwashers, laundry machines, sinks, and tubs. ("Enamelled" and "enamelling" are the preferred spellings in British English, while "enameled" and "enameling" are preferred in American English.)

History

Chinese cloisonné enamel wine pot, 18th century

Ancient Persians used this method for colouring and ornamenting the surface of metals by fusing over it brilliant colours that are decorated in an intricate design and called it Meenakari.

Mina is the feminine form of Minoo in Persian, meaning heaven. Mina refers to the Azure color of heaven. The Iranian craftsmen of Sasanian Empire era invented this art and Mongols spread it to India and other countries.[3] The ancient Egyptians applied enamels to stone objects, pottery, and sometimes jewellery, though to the last less often than in other ancient Middle Eastern cultures.

The ancient Greeks, Celts, Georgians, and Chinese also used enamel on metal objects.[4]

Enamel was also used to decorate glass vessels during the Roman period, and there is evidence of this as early as the late Republican and early Imperial periods in the Levant, Egypt, Britain and around the Black Sea.[5] Enamel powder could be produced in two ways, either by powdering coloured glass, or by mixing colourless glass powder with pigments such as a metallic oxide.[6]

Designs were either painted freehand or over the top of outline incisions, and the technique probably originated in metalworking.[5] Once painted, enamelled glass vessels needed to be fired at a temperature high enough to melt the applied powder, but low enough that the vessel itself was not melted.

Production is thought to have come to a peak in the Claudian period and persisted for some three hundred years,[5] though archaeological evidence for this technique is limited to some forty vessels or vessel fragments.[5] French tourist, Jean Chardin, who toured Iran during the Safavid rule, made a reference to an enamel work of Isfahan, which comprised a pattern of birds and animals on a floral background in light blue, green, yellow and red. Gold has been used traditionally for Meenakari Jewellery as it holds the enamel better, lasts longer and its lustre brings out the colours of the enamels.

Silver, a later introduction, is used for artifacts like boxes, bowls, spoons, and art pieces while copper which is used for handicraft products was introduced only after the Gold Control Act, which compelled the Meenakars to look for a material other than gold, was enforced in India.[3]

Initially, the work of Meenakari often went unnoticed as this art was traditionally used as a backing for the famous kundan or stone-studded jewellery. This also allowed the wearer to reverse the jewellery as also promised a special joy in the secret of the hidden design.[7]

In European art history, enamel was at its most important in the Middle Ages, beginning with the Late Romans and then the Byzantines, who began to use cloisonné enamel in imitation of cloisonné inlays of precious stones. Byzantine enamel style was widely adopted by the "barbarian" peoples of Migration Period northern Europe. The Byzantines then began to use cloisonné more freely to create images; this was also copied in Western Europe. The champlevé technique was considerably easier and very widely practiced in the Romanesque period. In Gothic art the finest work is in basse-taille and ronde-bosse techniques, but cheaper champlevé works continued to be produced in large numbers for a wider market.

From either Byzantium or the Islamic world, the cloisonné technique reached China in the 13-14th centuries. The first written reference to cloisonné is in a book from 1388, where it is called "Dashi ('Muslim') ware".[8] No Chinese pieces that are clearly from the 14th century are known; the earliest datable pieces are from the reign of the Xuande Emperor (1425–35), which, since they show a full use of Chinese styles, suggest considerable experience in the technique.

Cloisonné remained very popular in China until the 19th century and is still produced today. The most elaborate and most highly valued Chinese pieces are from the early Ming Dynasty, especially the reigns of the Xuande Emperor and Jingtai Emperor (1450–57), although 19th century or modern pieces are far more common.[9] Starting from the mid-19th century, the Japanese also produced large quantities of very high technical quality.[10]

Grey clouds, typical enamel cooking gear from the Dutch DRU factory, popular in the 1950s

More recently, the bright, jewel-like colors have made enamel a favoured choice for jewellery designers, including the Art Nouveau jewellers, for designers of bibelots such as the eggs of Peter Carl Fabergé and the enameled copper boxes of the Battersea enamellers,[11] and for artists such as George Stubbs and other painters of portrait miniatures.

A resurgence in enamel-based art took place near the end of the 20th century in the Soviet Union, led by artists like Alexei Maximov and Leonid Efros. In Australia, abstract artist Bernard Hesling brought the style into prominence with his variously sized steel plates.[12]

Enamel was first applied commercially to sheet iron and steel in Austria and Germany in about 1850.[13] Industrialization increased as the purity of raw materials increased and costs decreased. The wet application process started with the discovery of the use of clay to suspend frit in water. Developments that followed during the 20th century include enamelling-grade steel, cleaned-only surface preparation, automation, and ongoing improvements in efficiency, performance, and quality.[14]

Properties

Vitreous enamel can be applied to most metals. Most modern industrial enamel is applied to steel in which the carbon content is controlled to prevent unwanted reactions at the firing temperatures. Enamel can also be applied to gold, silver, copper, aluminium,[15] stainless steel,[16] and cast iron.[17]

Vitreous enamel has many useful properties: it is smooth, hard, chemically resistant, durable, scratch resistant (5-6 on the Mohs scale), has long-lasting colour fastness, is easy to clean, and cannot burn. Enamel is glass, not paint, so it does not fade under ultraviolet light.[18] A disadvantage of enamel is a tendency to crack or shatter when the substrate is stressed or bent, but modern enamels are relatively chip- and impact-resistant because of good thickness control and coefficients of thermal expansion well-matched to the metal. The Buick automobile company was founded by David Dunbar Buick with wealth earned by his development of improved enamelling processes, circa 1887, for sheet steel and cast iron. Such enameled ferrous material had, and still has, many applications: early 20th century and some modern advertising signs, interior oven walls, cooking pots, housing and interior walls of major kitchen appliances, housing and drums of clothes washers and dryers, sinks and cast iron bathtubs, farm storage silos, and processing equipment such as chemical reactors and pharmaceutical process tanks. Structures such as filling stations, bus stations and Lustron Houses had walls, ceilings and structural elements made of enamelled steel. One of the most widespread modern uses of enamel is in the production of quality chalk-boards and marker-boards (typically called 'blackboards' or 'whiteboards') where the resistance of enamel to wear and chemicals ensures that 'ghosting', or unerasable marks, do not occur, as happens with polymer boards. Since standard enamelling steel is magnetically attractive, it may also be used for magnet boards. Some new developments in the last ten years include enamel/non-stick hybrid coatings, sol-gel functional top-coats for enamels, enamels with a metallic appearance, and new easy-to-clean enamels.[19]

The key ingredient of vitreous enamel is finely ground glass called frit. Frit for enamelling steel is typically an alkali borosilicate glass with a thermal expansion and glass temperature suitable for coating steel. Raw materials are smelted together between 2,100 and 2,650 °F (1,150 and 1,450 °C) into a liquid glass that is directed out of the furnace and thermal shocked with either water or steel rollers into frit.[20]

Colour in enamel is obtained by the addition of various minerals, often metal oxides cobalt, praseodymium, iron, or neodymium. The latter creates delicate shades ranging from pure violet through wine-red and warm grey. Enamel can be transparent, opaque or opalescent (translucent). Different enamel colours can be mixed to make a new colour, in the manner of paint.

There are various types of frit, which may be applied in sequence. A ground coat is applied first; it usually contains smelted-in transition metal oxides such as cobalt, nickel, copper, manganese, and iron that facilitate adhesion to the metal. Next, clear and semi-opaque frits that contain material for producing colours are applied.

Techniques of artistic enameling

Old German enamel street sign

Industrial enamel application

On sheet steel, a ground coat layer is applied to create adhesion. The only surface preparation required for modern ground coats is degreasing of the steel with a mildly alkaline solution. White and coloured second "cover" coats of enamel are applied over the fired ground coat. For electrostatic enamels, the coloured enamel powder can be applied directly over a thin unfired ground coat "base coat" layer that is co-fired with the cover coat in a very efficient two-coat/one-fire process.

The frit in the ground coat contains smelted-in cobalt and/or nickel oxide as well as other transition metal oxides to catalyse the enamel-steel bonding reactions. During firing of the enamel at between 760 to 895 °C (1,400 to 1,643 °F), iron oxide scale first forms on the steel. The molten enamel dissolves the iron oxide and precipitates cobalt and nickel. The iron acts as the anode in an electrogalvanic reaction in which the iron is again oxidised, dissolved by the glass, and oxidised again with the available cobalt and nickel limiting the reaction. Finally, the surface becomes roughened with the glass anchored into the holes.[29]

Building cladding

Enamel coatings applied to steel panels offer protection to the core material whether cladding road tunnels, underground stations, building superstructures or other applications. It can also be specified as a curtain walling. Qualities of this structural material include:[30]

See also

Notes

  1. Campbell, 6
  2.  Chisholm, Hugh, ed. (1911). "Enamel". Encyclopædia Britannica (11th ed.). Cambridge University Press.
  3. 1 2 Meenakari
  4. Andrews, A.I. Porcelain Enamels, The Garrard Press: Champaign, IL, 1961 p. 1.
  5. 1 2 3 4 Rutti, B., Early Enamelled Glass, in Roman Glass: two centuries of art and invention, M. Newby and K. Painter, Editors. 1991, Society of Antiquaries of London: London.
  6. Gudenrath, W., Enameled Glass Vessels, 1425 BCE - 1800: The decorating Process. Journal of Glass Studies, 2006. 48
  7. http://www.iranreview.org/content/Documents/The_Art_of_Minakari_2.htm
  8. Sullivan, Michael, The arts of China, 4th edn, p. 239, University of California Press, 1999, Page 239
  9. Sullivan, Michael, The arts of China, 4th edn, p. 239, University of California Press, 1999, ISBN 0-520-21877-9, ISBN 978-0-520-21877-2, Google books
  10. "Japanese Cloisonné: the Seven Treasures". Victoria and Albert Museum. Retrieved 2009-08-30.
  11. http://www.vea.org.uk/what-is-enamel/
  12. database and e-research tool for art and design researchers. "Bernard Hesling :: biography at :: at Design and Art Australia Online". Daao.org.au. Retrieved 2013-12-25.
  13. Andrews, Andrew Irving, Porcelain enamels: the preparation, application, and properties of enamels, Garrard Press, 1961, Page 5
  14. Andrews, A.I. Porcelain Enamels, The Garrard Press: Champaign, IL, 1961 p. 5.
  15. Judd, Donald, “Porcelain Enameling Aluminum: An Overview,” Proceedings of the 59th Porcelain Enamel Institute Technical Forum, 45-51 (1997).
  16. Sullivan, J.D. and Nelson, F.W., "Stainless Steel Requires Special Enameling Procedures", Proceedings of the Porcelain Enamel Institute Technical Forum," 150-155 (1970).
  17. Pew, Steve, "The Who, What, Why, Where, and When of Cast Iron Enameling," Advances in Porcelain Enamel Technology, 177-186, (2010).
  18. Fedak, David and Baldwin, Charles, "A Comparison of Enameled and Stainless Steel Surfaces," Proceedings of the 67th Porcelain Enamel Institute Technical Forum, 45-54 (2005).
  19. Gavlenski, Jim and Baldwin, Charles, "Advanced Porcelain Enamel Coatings with Novel Properties," Proceedings of the 69th Porcelain Enamel Institute Technical Forum, 53-58, (2007).
  20. Andrews, A.I. Porcelain Enamels, The Garrard Press: Champaign, IL, 1961 p. 321-2.
  21. Campbell, 7, 33-41
  22. Campbell, 7, 17-32
  23. Campbell, 6, 10-17
  24. "Craft: Jewelry: Brooch". Luce Foundation Center for American Art. Smithsonian American Art Museum. Retrieved 29 March 2013.
  25. Campbell, 7
  26. British Museum collection database, "Scope note" for the term "enamelled"; other sources use different categories.
  27. Campbell, 38-42
  28. Campbell, 7, 42
  29. Feldman, Sid and Baldwin, Charles, "Surface Tension and Fusion Properties of Porcelain Enamels," Proceedings of the 69th Porcelain Enamel Institute Technical Forum, 1-10 (2008)
  30. Vitreous and porcelain enamels — Characteristics of enamel coatings applied to steel panels intended for architecture. Standards Policy and Strategy Committee. 2008. ISBN 978 0 580 72284 4.

References

Further reading

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