Background The name stainless steel covers a variety of corrosion resistant steels that contain a minimum of 11% Chromium. Changing the Chromium content and adding other elements like Nickel, Molybdenum, Titanium and Niobium changes the mechanical and physical properties of the steel.
This results in hundreds of different grades of stainless steel that are covered by a range of national and international standards. Grade FamiliesEach one of the grades is grouped into one of five stainless steel families. These families are named after their metallurgical microstructure. The five groups are austenitic, ferritic, duplex, martensitic and precipitation hardening.
Ferritic Stainless SteelsThe lack of other alloying elements means ferritic stainless steels are known as plain Chromium steels. They have a Chromium content between 12 and 18%. The carbon content in ferritic stainless steels is very low.
Ferritic stainless steels:
· Have moderate corrosion resistance
· Are not susceptible to stress corrosion
· Are magnetic
· Cannot be hardened by heat treatment
· Are always used in the annealed condition
· Poor weldability for most grades
Common ferritic grades include the proprietary grade 430 stainless steel and the cheapest stainless steel, grade 409 stainless steel. 409 stainless steel is the material of choice for automotive exhausts due to its combination of low price, corrosion resistance and excellent formability.

Austenitic Stainless SteelsAdding nickel to stainless steel in sufficient amounts, changes the microstructure to “austenite”.
70% of commercially produced stainless steels are austenitic. The most common grade of austenitic stainless steel is 304 (1.4301). Globally, 304 accounts for more than 50% of stainless steel consumed. A common name for 304 stainless is 18/8. This name refers to the average composition, 18% chromium and 8% nickel. It is sometimes used generically for austenitic stainless steels other than 304, even if the actual composition is vastly different.
Some of the features of austenitic stainless steels include:
· Excellent corrosion resistance
· Non-magnetic when annealed
· Rapidly work harden with cold work
· Not hardenable by heat treatment
· Ductile and readily formable
· Excellent weldability
· Hygienic with excellent cleanability
· Good performance at high temperatures
· Excellent performance at low temperatures
Other than 304 stainless steel, other common austenitic grades include the popular marine grade, 316 stainless steel and the machining bar grade, 303 stainless steel.
Martensitic Stainless SteelsThe first stainless steels to be developed for commercial applications were martensitic stainless steels. These steels were used for cutlery. When compared with other stainless steels, the martensitic stainless group have a relatively high carbon content (0.1 - 1.2%). Like ferritic stainless steels, they are plain chromium steels containing between 12 and 18% chromium.
Features of martensitic stainless steels include:
· Moderate corrosion resistance
· Heat treatable
· Magnetic
· Inability to be cold formed
· Poor weldability
Martensitic grades include 420 stainless steel, which is used in engineering applications like shafts and 440C stainless steel – the hardest and most abrasion resistant of all the stainless steels.
Duplex Stainless SteelsDuplex stainless steels get their name from the fact that they contain both a ferritic and austenitic microstructure. They have a relatively high chromium content of between 18 and 28%. Nickel content is moderate at 4.5 to 8%.
At this level, the nickel content is too low to generate a fully austenitic structure. This results in a duplex microstructure containing both ferritic and austenitic phases.
Duplex stainless steels also tend to contain 2.5-4% molybdenum.
The prime advantage of duplex stainless is the combination of properties derived from both austenitic and ferritic stainless steels.
Duplex stainless steels have:
· Excellent corrosion resistance
· Increased resistance to chloride attack
· Good resistance to stress corrosion cracking
· Tensile and yield strength higher than austenitic or ferritic grades
· Good weldability
· Good formability
With excellent corrosion resistance the common duplex grade, 2205 stainless steel, is used in heat exchangers, chemical tanks and refineries.
Precipitation Hardening GradesPrecipitation hardening stainless steels can be martensitic, semi-austenitic or austenitic. They offer the combined properties of corrosion resistance from austenitic grades with the heat treatability of martensitic grades.
Precipitation hardening grades, like 17-4 PH (also known as 630 stainless steel), are supplied as solution treated bars. They can then be machined before hardening.
The hardening process is a single, low temperature, ageing step.
Properties of precipitation hardening grades include:
· Good to moderate corrosion resistance
· Good weldability
· Very high strength
· Magnetic
SpecificationsGrade compositions, mechanical properties and production specifications are governed by a range of international and national standards for stainless steel. While the old AISI three digit stainless steel numbering system (e.g. 304 and 316) is still commonly used for the classification of stainless steel grades, new classification systems have been developed.
These systems include a 1-letter + 5-digit UNS number, like S30400, as defined by SAE and ASTM. European countries are adopting unified Euronorm standards. These countries are either replacing or adapting their own country specific standards to mirror the Euronorm standards. Other designations being replaced include old BS and EN numbers like 304S31 and 58E.
Some grades are not covered by standard numbers and could be proprietary grades or be named using standards for specialist products like welding wire.
Stainless steel standards are explained in detail in the British Stainless Steel Association “Guide to Stainless Steel Specifications”, also known as the BSSA “Blue Guide”.
The table 1 lists a range of stainless steel grades, their old BS designation, new UNS number and new EN designation.
Table 1. Stainless steel grades and their international equivalents
Grade UNS No BS Euronorm No. 301 S30100 301S21 1.4310 302 S30200 302S25 1.4319 303 S30300 303S31 1.4305 304 S30400 304S31 1.4301 304L S30403 304S11 1.4306 304H S30409 - 1.4948 (302HQ) S30430 394S17 1.4567 305 S30500 305S19 1.4303 309S S30908 309S24 1.4833 310 S31000 310S24 1.4840 310S S31008 310S16 1.4845 314 S31400 314S25 1.4841 316 S31600 316S31 1.4401 316L S31603 316S11 1.4404 316H S31609 316S51 - 316Ti S31635 320S31 1.4571 321 S32100 321S31 1.4541 347 S34700 347S31 1.4550 403 S40300 403S17 1.4000 405 S40500 405S17 1.4002 409 S40900 409S19 1.4512 410 S41000 410S21 1.4006 416 S41600 416S21 1.4005 420 S42000 420S37 1.4021 430 S43000 430S17 1.4016 440C S44004 - 1.4125 444 S44400 - 1.4521 630 S17400 - 1.4542 (904L) N08904 904S13 1.4539 (253MA) S30815 - 1.4835 (2205) S31803 318S13 1.4462 (3CR12) S41003 - 1.4003 (4565S) S34565 - 1.4565 (Zeron100) S32760 - 1.4501 (UR52N+) S32520 - 1.4507
ASTM does not recognise the designations in brackets. Many other grades and specifications are available.
Material supplied by Aalco has been manufactured to comply with a number of standards depending upon the product. Standards also cover the finish of the material.
Mechanical PropertiesRequired mechanical properties are normally given in purchase specifications for stainless steels. Minimum mechanical properties are also given by the various standards relevant to the material and product form. Meeting these standard mechanical properties indicates that the material has been properly manufactured to an appropriate quality system. Engineers can then confidently utilise the material in structures that meet safe working loads and pressures.
Mechanical properties specified for flat rolled products are normally tensile strength, yield stress (or proof stress), elongation and Brinell or Rockwell hardness. Property requirements for bar, tube, pipe and fittings typically state tensile strength and yield stress.
Yield StrengthUnlike mild steels, the yield strength of annealed austenitic stainless steels is a very low proportion of the tensile strength. Mild steel yield strength is typically 65-70% of the tensile strength. This figure tends to only be 40-45% in the austenitic stainless family.
Cold working rapidly and greatly increases the yield strength. Some forms of stainless steel, like spring tempered wire, can be cold worked to lift the yield strength to 80-95% of the tensile strength.
DuctilityThe combination of high work hardening rates and high elongation / ductility makes stainless steels very easy to fabricate. With this property combination, stainless steel can be severely deformed in operations like deep drawing.
Ductility is normally measured as the % elongation before fracture during tensile testing. Annealed austenitic stainless steels have exceptionally high elongations. Typical figures are 60-70%.
HardnessHardness is the resistance to penetration of the material surface. Hardness testers measure the depth that a very hard indenter can be pushed into the surface of a material. Brinell, Rockwell and Vickers machines are used. Each of these has a different shaped indenter and method of applying the known force. Conversions between the different scales are therefore only approximate.
Martensitic and precipitation hardening grades can be hardened by heat treatment. Other grades can be hardened through cold working.
Tensile StrengthTensile strength is generally the only mechanical property required to define bar and wire products. Identical material grades may be used at various tensile strengths for completely different applications. The supplied tensile strength of bar and wire products directly relates to the final use after fabrication.
Spring wire tends to have the highest tensile strength after fabrication. The high strength is imparted by cold working into coiled springs. Without this high strength the wire would not function properly as a spring.
Such high tensile strengths are not required for wire to be used in forming or weaving processes. Wire or bar used as raw material for fasteners, like bolts and screws, needs to be soft enough for a head and thread to be formed but still strong enough to perform adequately in service.
The different families of stainless steels tend to have different tensile and yield strengths. These typical strengths for annealed material are outlined in Table 2.
Table 2. Typical strength for annealed stainless steel from different families
Tensile Strength Yield Strength Austenitic 600 250 Duplex 700 450 Ferritic 500 280 Martensitic 650 350 Precipitation Hardening 1100 1000
Physical PropertiesThe reason for choosing stainless steel is normally due to advantages given by physical properties such as corrosion resistance.
In addition to corrosion resistance, the advantageous physical properties of stainless steel include:
· High and low temperature resistance
· Ease of fabrication
· High Strength
· Aesthetic appeal
· Hygiene and ease of cleaning
· Long life cycle
· Recyclable
· Low magnetic permeability
Corrosion ResistanceGood corrosion resistance is a feature of all stainless steels. Low alloy grades can resist corrosion in normal conditions. Higher alloys resist corrosion by most acids, alkaline solutions and chloride environments.
The corrosion resistance of stainless steels is due to their chromium content. In general, stainless steels contain a minimum of around 10.5% chromium. The chromium in the alloy forms a self-healing protective clear oxide layer that forms spontaneously in air. The self healing nature of the oxide layer means the corrosion resistance remains intact regardless of fabrication methods. Even if the material surface is cut or damaged, it will self heal and corrosion resistance will be maintained.
Extreme Temperature ResistanceSome stainless steel grades can resist scaling and retain high strength at very high temperatures. Other grades maintain high mechanical properties at cryogenic temperatures.
Simple FabricationMost grades of stainless steel can be cut, welded, formed, machined and fabricated using standard methods and equipment used for other types of steel.
High StrengthComponent designs and fabrication methods can be altered to take advantage of the work hardening of stainless steels that occurs when they are cold worked. The resultant high strengths can allow the use of thinner material, leading to lower weights and costs.
Other stainless steels can be heat treated to increase strength.
Aesthetic AppealStainless steel can be supplied with a range of surface finishes. It can also be polished after fabrication to give the desired finish. The finish of stainless steel is easy to clean and maintain.

Hygiene and Ease Of CleaningStainless steel is non-toxic and readily cleaned. This makes stainless steel the material of choice for use in hospitals, kitchens, food, drink and pharmaceutical processing plants.
Long Life CycleThe durability and corrosion resistance of stainless steel means it will outlast many competing products. The low maintenance characteristics also add to stainless steel often being the lowest cost choice in a life cycle cost comparison.
RecyclableStainless steel is fully recyclable. New stainless steel normally contains between 50 and 80% recycled material. Scrap stainless steel can be stored without degradation to its value as a raw material.
Magnetic PermeabilityMagnetic permeability is the ability of a material to attract a magnet. The austenitic grades are the only stainless steel grades that are not magnetic. Cold working can induce a limited degree of magnetism in austenitic grades other than 310 and 316 stainless steels.