Classification of Steel

MATERIAL SCIENCE AND ENGINEERING
Classification
Of
Steels

REFERENCES
 Materials Science and Engineering, V. Raghavan,
Fifth Edition, Prentice Hall of India Pvt. Ltd., New
Delhi, 2004.
 Materials Science and Engineering: An Introduction,
William D. Callister
John Wiley & Sons, 2010.
ONLINE - Nptel

Ferrous Materials
Ferrous
Steels Cast iron
Low Alloy High Alloy
Tool steel Stainless steel

FERROUS MATERIAL - STEELS
.
–Low Carbon (<0.25 wt% C)
–Medium Carbon (0.25 to 0.60 wt% C)
–High Carbon (0.6 to 1.4 wt% C)
• Steels - alloys of iron-carbon.
- May contain other alloying elements.
• Several grades are available
• Low Alloy (<10 wt%)
– Stainless Steel (>11 wt% Cr)
- Tool Steel
•High Alloy

EFFECT OF CARBON ON PROPERTIES OF STEELS

Low Carbon Steel
- Also known as Mild Steel
- Tensile strength of 555 N/mm
- Hardness of 140 BHN
- Bright fibrous structure
- Tough , malleable , ductile and more elastic than
wrought iron
- Melting point 1410

Low Carbon Steel
Plain carbon steels - very low content of alloying elements
and small amounts of Mn.
Most abundant grade of steel is low carbon steel –
greatest quantity produced; least expensive.
Not responsive to heat treatment; cold working needed to
improve the strength.
Good Weldability and machinability
High Strength, Low Alloy (HSLA) steels - alloying elements
(like Cu, V, Ni and Mo) up to 10 wt %; have higher strengths
and may be heat treated.

LOW CARBON STEEL
Compositions of some low carbon and low alloy steels

AISI - SAE CLASSIFICATION SYSTEM
AISI XXXX
American Iron and Steel Institute (AISI)
 classifies alloys by chemistry
 4 digit number
 1st number is the major alloying element
 2nd number designates the subgroup alloying
element OR the relative percent of primary
alloying element.
 last two numbers approximate amount of
carbon (expresses in 0.01%)

AISI - SAE CLASSIFICATION
SYSTEM
 letter prefix to designate the process used to produce the
steel
 E = electric furnace
 X = indicates permissible variations
 If a letter is inserted between the 2nd and 3rd number
 B = boron has been added
 L = lead has been added
 Letter suffix
 H = when hardenability is a major requirement
 Other designation organizations
 ASTM and MIL

MEDIUM CARBON STEEL
Carbon content in the range of 0.3 – 0.6%.
Can be heat treated - austenitizing, quenching and then
tempering.
Most often used in tempered condition – tempered
martensite
Medium carbon steels have low hardenability
Addition of Cr, Ni, Mo improves the heat treating capacity
Heat treated alloys are stronger but have lower ductility
Typical applications – Railway wheels and tracks, gears,
crankshafts.

MEDIUM CARBON STEEL
- Bright fibrous structure when fractured
- Tough and more elastic in comparison to wrought iron
- Eaisly forged , welded , elongated due to ductility
- Good malleability
- Its tensile strength is better than cast iron and wrought iron
- Compressive strength is better than wrought iron but lesser
than cast iron

STRUCTURAL STEELS
- Possess high strength and toughness
- resistance to softening at elevated temperatures
- resistance to corrosion
- possess weldability , workability & high
hardenability
- principle alloying elements chromium , nickel ,
manganese

EFFECTS OF ALLOYING ELEMENTS ON STEEL
 Manganese contributes to strength and hardness; dependent upon the carbon
content. Increasing the manganese content decreases ductility and weldability.
Manganese has a significant effect on the hardenability of steel.
 Phosphorus increases strength and hardness and decreases ductility and notch
impact toughness of steel. The adverse effects on ductility and toughness are
greater in quenched and tempered higher-carbon steels.
 Sulfur decreases ductility and notch impact toughness especially in the transverse
direction. Weldability decreases with increasing sulfur content. Sulfur is found
primarily in the form of sulfide inclusions.
 Silicon is one of the principal deoxidizers used in steelmaking. Silicon is less
effective than manganese in increasing as-rolled strength and hardness. In low-
carbon steels, silicon is generally detrimental to surface quality.
 Copper in significant amounts is detrimental to hot-working steels. Copper can be
detrimental to surface quality. Copper is beneficial to atmospheric corrosion
resistance when present in amounts exceeding 0.20%.
 Nickel is a ferrite strengthener. Nickel does not form carbides in steel. It remains
in solution in ferrite, strengthening and toughening the ferrite phase. Nickel
increases the hardenability and impact strength of steels.
 Molybdenum increases the hardenability of steel. It enhances the creep strength
of low-alloy steels at elevated temperatures.

Classification of Steel

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