Chromium - the main alloying element – produces a transformation free ferritic microstructure. Additions of aluminium and silicon stabilize the ferrite and increase scale resistance. Excellent resistance to oxidizing and reducing sulphurous gases, compatibility with molten metals, high thermal conductivity and low thermal expansion, are features that complement the properties of our existing high temperature austenitic stainless steels. Four grades with alternating chromium contents allow a broad variety of heat and corrosion resistance according to the requirements in the respective application. The two lower alloyed grades - 4713 and 4724 - are best suited for oxidizing sulphur environments and exposures to the “low” high temperature ranges, where austenitic stainless steels undergo structural changes that lead to embrittlement.

With higher chromium contents, 4742 and 4762 cover applications that require higher service temperatures and insensitivity to reducing sulphurous gases. Since austenitic stainless steels form low-melting-point nickel sulphides, which destroy the protective oxide layer, ferritic material is recommended. 4742 can be applied in the range 700 - 1000°C. With 18% chromium, it shows very good resistance to reducing sulphurous gases in addition to oxidizing sulphur-containing atmospheres.

All four grades are included in the EN 10095 – the standard for heat resistant steels and nickel alloys. They are produced as quarto plates from 2 mm in thickness. Taylor made plates allow individual dimensioning, provide ready to use material, and thus eliminate scrap.

Datasheets on the high temperature ferritic stainless steels further inform about mechanical and physical, corrosion resistance and give recommendations for proper fabrication etc.