Stainless Steel

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Property

Constituents

The quality of stainless steel is imparted to steels by the presence of at least 12% of chromium in the steel. Oxidation and / or corrosion produce a dense adherent oxide film which acts as a barrier to further corrosion.

Martensitic steel 13% chromium, and more than 0.1% carbon
Ferritic steel 13-17% chromium, and < 0.08% carbon
Austhentic steel Min 8% nickel, 17-24% chromium, max 0.1% carbon

Grade

Based on BS 1449: Part 2: 1983

Grade
Typical composition (%)
 
0.2% proof stress (MPa)
Ultimate Strength (MPa)
Elongation (%)
Sensitization (min)
.
C
Cr
Ni
other
Ferritic
.
.
.
.
.
.
.
.
403 S17
0.08
13
.
.
245
420
20
.
403 S17
0.08
17
.
.
245
430
20
.
Austhenitic
.
.
.
.
.
.
.
.
304 S15
0.05
18
9
.
195
500
40
15
309 S24
0.12
23
14
.
205
510
40
0
310 S24
0.12
24
20
.
205
510
40
0
316 S11
0.03
17
12
2.25 Mo
190
490
40
30
317 S12
0.03
18
15
3.5 Mo
195
490
40
30
320 S31
0.08
17
12
2.25 Mo Ti=5C
210
510
40
30

Classification

  • Stainless steels can be grouped according to chemical composition and response to heat treatment as follows:
    1. ferritic steels, which are non-hardenable steels with 15 to 30% chromium and a low carbon content of 0.08 to 0.20%;
    2. martensitic steels, which are hardenable by quenching and contain 10 to 18% chromium and 0.08 to 1.10% carbon; and
    3. austenitic steels, which are hardenable without quenching and contain 16 to 26% chromium and 6 to 22% nickel.
  • Types 301, 302, 303, 304 and 316 are austenitic steels, and
  • Type 430 is a ferritic stainless steel, which is somewhat less resistant to corrosion than the austenitic stainless steels.
  • Two austenitic stainless steels, type 201 and 202, are available for construction applications.
  • Type 201 is an austenitic alloy that is similar to type 301 and 302 but is stronger, harder, and characterized by more spring back in fabrication.
  • Types 305 and 410 are also used, but primarily for bolts, nuts, screws, and other types of fasteners.

Typical content of main alloying elements in the principal grades of stainless steels:

Family

EN 10088

designation 

Popular name
Weight (%)
Cr
Ni
Mo
Austenitic
1.4301
304
18
9
Austenitic
1.4301
316
17
12
2

Added Elements

Nickel and manganese are important added elements that produce special characteristics such as strength, toughness, and ease of fabrication in stainless steels. Columbium (niobium), molybdenum, phosphorus, selenium, silicon, sulphur, titanium, and zirconium are also used to give special characteristics.

Effects of Chromium

The chromium in these alloys is thought to be the element that gives the corrosion resistance. Part of the chromium combines with the carbon and some of the iron in steel to form chromium-iron carbides, and the remainder dissolves in the iron. The best corrosion resistance is obtained when as much of the chromium as possible is dissolved in the iron and as little as possible is combined in the carbide form. A thin, stable, hard, continuous, invisible film is formed on the surface, which acts as a barrier against progressive attack by corrosive agents, as long as oxygen in some form is present.

Mechanical and Physical Properties

Steel designation
Density (kg/m³)
Minimum 0.2% proof strength or yield strength(MN/m²)
Modulus of elasticity (kN/mm²)
Thermal expansion 20-100°C (10-6/°C)
Thermal conductivity at 20°C (W/m°C)
Heat capacity at 20°C 
(J/Kg°C)
1.4301(304)
7900
210-230*
200
16.0
15.0
500
1.4401(316)
8000
220-240*
200
16.0
15.0
500

Note:
* The higher value is applicable for thickness up to 6 mm.
** The lower value is applicable for thickness up to 75mm.

Material Properties

Property .
Density 8000 kg/m³
Young’s modulus 195 t/ 190 l kN/mm²
Thermal Conductivity 15 W/ mºC
Co-efficient of thermal expansion 1.6x 10-5/ ºC
Corrosion Resistance Excellent
Melting point 1425 ºC
Recyclability Excellent
Primary embodied energy * 150 GJ/ m³

* Data supply by BRE

Modulus Elasticity

Stainless Steel .
Austenitic 190-205
Ferritic 200-215
Martensitic 215

Fire and Heat Resistance

Special high chromium and nickel-alloyed grades resist scaling and retain strength at high temperatures.

Corrosion Resistance

Lower alloyed grades resist corrosion in atmospheric and pure water environments, while high-alloyed grades can resist corrosion in most acids, alkaline solutions, and chlorine bearing environments, properties which are utilized in process plants.

Impact Resistance

The austenitic microstructure of the 300 series provides high toughness, from elevated temperatures to far below freezing, making these steels particularly suited to cryogenic applications.