Lecture 38: Types of Steels, Alloying Effects

Summary

This lecture covers various types of steels, the effects of alloying elements on their properties, and issues related to stainless steel, such as sensitization and grain boundary corrosion. It includes details on elements like chromium, manganese, nickel, and molybdenum. This is geared towards an undergraduate materials science course.

Full Transcript

Lecture 38

04-11-2024

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 Module: 6 Metallic Materials

Module:6 Metallic Materials 6 hours

Steels – Types of Steels, Effect of alloying elements on structure and
properties of steels, Alloy Steel – Tool and Die Steel, Stainless steel,
Speciality steel, Cast iron- White, Grey, Malleable and Nodular - Properties
and application of cast irons. Non-ferrous Alloys, Aluminium, copper,
Nickel, Magnesium and Titanium.

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 Steels – Types of Steels

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 Effect of alloying elements on structure & properties

Alloying elements are added to steels for one, or more, of the following reasons:
1) To improve mechanical properties by controlling hardenability and permitting
higher tempering temperature while maintaining high strength and ductility
2) To improve high- or low-temperature mechanical properties
3) To increase resistance to chemical attack or thermal oxidation
4) To influence special properties such as magnetic permeability and neutron
absorption

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 Steels – Types of Steels

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 Effect of alloying elements on structure & properties

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 Effect of alloying elements on structure & properties
Boron (B):
 Small amounts substantially increase hardenability
 Boron-treated steels will usually contain 0.0005–0.003% boron
 Boron is effective with low-carbon alloy steels
 Its effectiveness decreases with increasing carbon content
 Boron is not recommended for steels containing >0.6% carbon.
Manganese (Mn):
 Increases hardenability and is a carbide former (Mn3C) above a threshold value
 In constructional steel alloys, it increases the critical cooling rate
 It therefore facilitates deep hardening

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 Effect of alloying elements on structure & properties

Nickel (Ni):
 Increases hardenability by decreasing the critical cooling rate necessary to produce
hardening as a result of quenching
 It affects austenite transformation by depressing Ac and Ar critical temperatures
 Nickel does not form carbide structures
 When combined with Cr, nickel produces alloy steels with
 Greater hardenability
 Higher impact strength
 Higher fatigue resistance than is possible with carbon steels

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 Effect of alloying elements on structure & properties
Chromium (Cr):
 Chromium is a strong carbide former
 In the presence of C and Fe, Cr forms a complex series of carbide structures
 Complex Cr carbides dissolve in austenite slowly
 Cr greatly increases hardenability and increases oxidation & corrosion resistance

Vanadium (V):
 Vanadium is a strong carbide-forming element
 Increases hardenability & promotes finer grain size
 V decreases high-temperature grain growth
 Vanadium increases hardness at elevated temperature
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 Effect of alloying elements on structure & properties
Molybdenum (Mo):
 Molybdenum may form complex carbide structures.
 Increases hardenability and is more potent than chromium
 It is often used in combination with nickel and/or chromium
 In solid solution, Mo ↓ transformation rates, and this increases depth of hardening.

Silicon (Si):
 It increases the critical temperature by amounts that vary with carbon content
 Required austenitizing temperatures are increased
 Silicon is not a carbide former

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 Issues with Stainless Steel materials
 Stainless steel shows the sensitivity to

 Grain boundary corrosion

 Stress corrosion cracking of grain boundary type

 Happens in specific corrosive environment

 Caused by the deterioration of corrosion resistance near GB

 Concentration of Cr is reduced by the precipitation of chromium carbide at GB

 Happens when stainless steel is subjected to specific thermal history

 This is called sensitization

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 Issues with Stainless Steel materials

 Sensitization is a dynamic phenomenon: Occurs in shorter time as temperature is
higher

 Sensitization of austenitic stainless steel occurs when it is heated to 500 to 850C

 Sensitization of austenitic stainless steel vanishes by quenching from the solution
treatment temperature above 1000C

 In the case of ferritic stainless steel, the sensitization occurs when it is quenched
from high temperature above 900C

 Sensitization vanishes by the annealing around 800C

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 Issues with Stainless Steel materials

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