Jump to content

Main menu Navigation ●Main page ●Contents ●Current events ●Random article ●About Wikipedia ●Contact us ●Donate Contribute ●Help ●Learn to edit ●Community portal ●Recent changes ●Upload file

●Create account ●Log in ●Create account ● Log in Pages for logged out editors learn more ●Contributions ●Talk

(Top) 1 History 2 Metallurgy 3 Chemical composition 4 Corrosion resistance 5 Physical properties 6 Mechanical properties 7 Applications 8 References

Ferritic stainless steel

●Afrikaans ●日本語 ●Slovenščina ●Türkçe ●中文 Edit links ●Article ●Talk ●Read ●Edit ●View history Tools Actions ●Read ●Edit ●View history General ●What links here ●Related changes ●Upload file ●Special pages ●Permanent link ●Page information ●Cite this page ●Get shortened URL ●Download QR code ●Wikidata item Print/export ●Download as PDF ●Printable version Appearance From Wikipedia, the free encyclopedia

Ferritic stainless steel (SUS445J2) is used for the roof exterior of the Kyocera Dome Osaka, Japan.^[1]

Ferritic stainless steel^[2]^[3] forms one of the five stainless steel families, the other four being austenitic, martensitic, duplex stainless steels, and precipitation hardened.^[4] For example, many of AISI 400-series of stainless steels are ferritic steels. By comparison with austenitic types, these are less hardenable by cold working, less weldable, and should not be used at cryogenic temperatures. Some types, like the 430, have excellent corrosion resistance and are very heat tolerant.^[5]

History[edit]

Canadian-born engineer Frederick Mark Becket (1875-1942) at Union Carbide industrialised ferritic stainless steel around 1912, on the basis of "using silicon instead of carbon as a reducing agent in metal production, thus making low-carbon ferroalloys and certain steels practical".^[6] He discovered a ferrous alloy with 25-27% Chromium that "was the first of the high-chromium alloys that became known as heat-resisting stainless steel."^[7]

Ferritic stainless steels were discovered early but it was only in the 1980s that the conditions were met for their growth:

It was possible to obtain very low carbon levels at the steelmaking stage.
Weldable grades were developed.
Thermomechanical processing solved the problems of "roping" and "ridging" that led to inhomogenous deformation during deep drawing and to textured surfaces.
End-user markets (such as that of domestic appliances) demanded less expensive grades with a more stable price at a time when there were large variations of the price of nickel.^[8] Ferritic stainless steel grades became attractive for some applications such as houseware.^[9]

Metallurgy[edit]

Fe – Cr Phase diagram

To qualify as stainless steel, Fe-base alloys must contain at least 10.5%Cr.

The iron-chromium phase diagram shows that up to about 13%Cr, the steel undergoes successive transformations upon cooling from the liquid phase from ferritic α phase to austenitic γ phase and back to α. When some carbon is present, and if cooling occurs quickly, some of the austenite will transform into martensite. Tempering/annealing will transform the martensitic structure into ferrite and carbides.

Above about 17%Cr the steel will have a ferritic structure at all temperatures.

Above 25%Cr the sigma phase may appear for relatively long times at temperature and induce room temperature embrittlement.

Chemical composition[edit]

Chemical composition of a few grades of stainless steel.
Main alloying elements only: chromium (Cr) along with:
Ni, Mo, Nb, Ti, and C, N; Balance: Fe
AISI / ASTM	EN	Weight %
AISI / ASTM	EN	Cr	Other elements	Melts at
405	1.4000	12.0 – 14.0	—
409L	1.4512	10.5 – 12.5	6(C+N)<Ti<0.65
410L	1.4003	10.5 – 12.5	0.3<Ni<1.0
430	1.4016	16.0 – 18.0	—	1510^[10]
439	1.4510	16.0 – 18.0	0.15+4(C+N)<Ti<0.8
430Ti	1.4511	16.0 – 18.0	Ti: 0.6
441	1.4509	17.5 – 18.5	0.1<Ti<0.6 0.3+3C<Nb<1.0
434	1.4113	16.0 – 18.0	0.9<Mo<1.4
436	1.4513	16.0 – 18.0	0.9<Mo<1.4 0.3<Ti<0.6
444	1.4521	17.0 – 20.0	1.8<Mo<2.5 0.15+4(C+N)<Ti+Nb<0.8
447	1.4592	28 – 30.0	3.5<Mo<4.5 0.15+4(C+N)<Ti<0.8

Corrosion resistance[edit]

The pitting corrosion resistance of stainless steels is estimated by the pitting resistance equivalent number (PREN).

PREN = %Cr + 3.3%Mo + 16%N

Where the Cr, Mo, and N, terms correspond to the contents by weight %ofchromium, molybdenum and nitrogen respectively in the steel.

Nickel (Ni) has no role in the pitting corrosion resistance, so ferritic stainless steels can be as resistant to this form of corrosion as austenitic grades.

In addition, ferritic grades are very resistant to stress corrosion cracking (SCC).

Physical properties[edit]

Ferritic stainless steels are magnetic. Some of their important physical, electrical, thermal and mechanical properties are given in the table here below.

Physical properties of the most common ferritic stainless steels
AISI / ASTM	Density (g/cm³)	Electrical resistance (μΩ·m)	Thermal conductivity at 20 °C (W/(m·K))	Specific heat 0...100 °C (J/(kg·K))	Thermal expansion 0...600 °C (10⁻⁶/K)	Young's modulus (GPa)
409 / 410	7.7	0.58	25	460	12	220
430	7.7	0.60	25	460	11.5	220
430Ti / 439 / 441	7.7	0.60	25	460	11.5	220
434 / 436 / 444	7.7	0.60	23	460	11.5	220
447	7.7	0.62	17	460	11	220

Compared to austenitic stainless steels, they offer a better thermal conductivity, a plus for applications such as heat exchangers. The thermal expansion coefficient, close to that of carbon steel, facilitates the welding to carbon steels.

Mechanical properties[edit]

Mechanical properties (cold rolled)
ASTM A240				EN 10088-2
—	UTS (MPa, min)	0.2% yield stress (MPa, min)	Elongation (%, min)	—	UTS (MPa)	0.2% yield stress (MPa, min)	Elongation (%, min)
409	390	170	20	1.4512	380 – 560	220	25
410	415	205	20	1.4003	450 – 650	320	20
430	450	205	22	1.4016	450 – 600	280	18
439	415	205	22	1.4510	420 – 600	240	23
441	415	205	22	1.4509	430 – 630	250	18
434	450	240	22	1.4113	450 – 630	280	18
436	450	240	22	1.4526	480 – 560	300	25
444	415	275	20	1.4521	420 – 640	320	20

Applications[edit]

Lower-cost of recent-production kitchenware
White goods
Solar heaters
Slate hooks
Coins

References[edit]

^ "屋根:大阪ドーム" (in Japanese). Japan Stainless Steel Association. Retrieved 12 October 2023.

^ Lacombe, P.; Baroux, B.; Beranger, G., eds. (1990). Les Aciers Inoxydables. Les éditions de Physique. pp. Chapters 14 and 15. ISBN 2-86883-142-7.

^ The ferritic solution. 2007. ISBN 978-2-930069-51-7. Archived from the original on 21 December 2019. Retrieved 14 July 2019.

^ The International Nickel Company (1974). "Standard Wrought Austenitic Stainless Steels". Nickel Institute. Archived from the original on 9 January 2018. Retrieved 9 January 2018.

^ "304 vs 430 stainless steel". Reliance Foundry Co. Ltd. Retrieved 28 May 2022.

^ "Frederick Mark Becket American metallurgist". Encyclopaedia Britannica. 7 January 2021.

^ Cobb, Harold M. (2012). Dictionary of Metals. ASM International. p. 307. ISBN 9781615039920.

^ Charles, J.; Mithieux, J.D.; Santacreu, P.; Peguet, L. (2009). "The ferritic family: The appropriate answer to nickel volatility?". Revue de Métallurgie. 106: 124–139. doi:10.1051/metal/2009024.

^ Ronchi, Gaetano (2012). "Stainless Steel for House-ware". Metal Bulletin.

^ "Stainless steel melting points". Thyssenkrupp Materials (UK) Ltd. Retrieved 28 May 2022.

Retrieved from "https://en.wikipedia.org/w/index.php?title=Ferritic_stainless_steel&oldid=1218093930" Category: ●Stainless steel Hidden categories: ●CS1 Japanese-language sources (ja) ●Articles with short description ●Short description matches Wikidata ●Use dmy dates from October 2023 ●This page was last edited on 9 April 2024, at 17:43 (UTC). ●Text is available under the Creative Commons Attribution-ShareAlike License 4.0; additional terms may apply. By using this site, you agree to the Terms of Use and Privacy Policy. Wikipedia® is a registered trademark of the Wikimedia Foundation, Inc., a non-profit organization. ●Privacy policy ●About Wikipedia ●Disclaimers ●Contact Wikipedia ●Code of Conduct ●Developers ●Statistics ●Cookie statement ●Mobile view