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AISL/DE- Austenitic Stainless Steel

Steel data sheets

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Valbruna Grade

AISL/DE

Steel type

Austenitic Stainless Steel

Description of material

AISL/DE is a low Carbon, Cr-Ni austenitic stainless steel with a marginally higher nickel content than grade 304L. It has good general corrosion resistance as well as good intergranular corrosion after welding processes.

Applications

AISL/DE is suitable for the fabrication of many products such as flanges, valves, bolting, screws, pumps shafts, food/beverages industry equipment, storage tanks, pharmaceutical devices, many organic chemicals and parts working in mild to medium corrosive environments.

Melting practices

Argon Oxygen Decarburization

Corrosion resistance

AISL/DE is resistant to fresh water, many organic chemicals and inorganic compounds, atmospheric corrosion, rural applications and sterilizing solutions where the chloride content is low. Pitting and crevice corrosion may occur in chloride environments if concentration, pH and temperature are at determinate levels. As with other standard austenitic grades, AISL/DE suffers from stress corrosion cracking about forty /fifty degrees (C°) above room temperature and above certain levels of stress and halogen concentrations. Very strain hardened structures increase the risk of stress corrosion cracking. Its intergranular corrosion resistance is very good. It should be noted that this grade, as for every kind of stainless steel, surfaces should be free of contaminant and scale, heat tint, and passivated for optimum resistance to corrosion.

Cold working

AISL/DE offers a higher cold working hardening factor compared to Copper alloy austenitic grades. These grades, such as AISRUH and AISRU, whose chemical balance provides a higher cold deformability, are the right choice if high cold heading performance were required and where the high Copper content would not be a jeopardy in certain applications. AISL/DE has good polish-ability or mirror finishing capacity, but it should be pointed out that these properties improve with a fine grain structure, harder than a fully annealed one.

Machinability

AISL/DE has generally a poor machinability due to a low Sulfur content. In the case of a structure of AISL/DE which is micro–resulphured, this creates an advantage thanks a better chip breaking ability. The best performance is obtained when employing the correct machining parameters. However, Austenitic grades are different from Ferritic and Alloy steels and require more rigid and powerful machines in addition to the correct choice of tools, coatings and cutting fluids. The roughness of machined parts improves in the case of a harder structure than the fully annealed one.

Weldability

AISL/DE has normally a special chemical composition which helps to avoid solidification cracks in the fused-zone of autogenous welds due to a suitable Ferrite balance. Moreover, the Cr/Ni equivalent balance of the supplied product should be evaluated to avoid the risk of solidification cracks in the fused-zone of high energy autogenous welds. In the case of filler metal welding, a filler with a matching composition of AISL/DE or over alloyed is recommended to maintain weld steel properties. Neither preheating nor post welding heat treatment is required. Nevertheless, in the case of aggressive environments, a post welding heat treatment is suggested.

Hot working

AISL/DE offers a very good hot workability and is usually supplied as billets, blooms, or ingots. No preheating is required. In Primary hot transformation processes, a high temperature homogenization of large ingots and dynamic recrystallization parameters should be rightly evaluated. In the case of open die forging of large ingots and shapes, AISL/DE offers a good hot plasticity if a suitable soaking and a right temperature are applied. In Secondary hot transformation processes, such as extrusion, rolling or close die forging, temperatures, strain and strain rate should be well considered because they influence the properties of the austenitic structure. Suitable strain in terms of section reduction ( for instance: 15-30%) at a lower range of hot working temperature is recommended in order to obtain a fine grain austenitic structure which is very important for mechanical, fatigue and corrosion resistance properties and makes it easier for ultrasonic testing to detect small indications as required by several International Norms. Small forgings can be cooled rapidly in air or water.

Designations

W.N. 1.4306
EN X2CrNi19-11
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