Steels: Equilibrium Transformations PDF

Summary

This document discusses steels: equilibrium transformations, focusing on the Fe-C phase diagram and the influence of alloying elements. It includes learning objectives for understanding phases, microconstituents, and invariant reactions related to steels. The document appears to be part of a university materials science course, providing a technical exposition on the subject.

Full Transcript

Diagramas dediagram
Fe-C phase fase Fe-C

SESSION 9

STEELS: EQUILIBRIUM
TRANSFORMATIONS

Department of Materials Science and Chemical Engineering
Escuela Politécnica Superior
Universidad Carlos III de Madrid

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 Diagramas dediagram
Fe-C phase fase Fe-C

Content

The Fe-C system
Equilibrium phase transformations
Development of microstructure in steels
Eutectoid steels
Hypoeutectoid steels
Hypereutectoid steels
Influence of the alloying elements in the metastable Fe-C system

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Fe-C phase fase Fe-C

Learning objectives

Identify phases and microconstituents in the Fe-C phase diagram
Learn the invariant reactions present in the Fe-C phase diagram
Determine composition, mass fractions of the phases and the
microconstituents by using the lever rule
Describe the microstructure evolution regarding the phases and
microconstituents upon cooling
Learn how the alloying elements can affect the Fe-C phase diagram

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Fe-C phase fase Fe-C

Allotropic phases of Fe

LIQUID Allotropy: existence of a chemical element in two or
more forms, which may differ in the arrangement of
1535˚C atoms in crystalline solids.
Fe- (BCC)
1390˚C

Fe- (FCC)

910˚C

Fe-α (BCC)

Fe experiences two changes in
Room Temperature crystal structure before it melts.
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Fe-C phase fase Fe-C

Fe-C phase diagram

peritectic

Metastable diagram
eutectic ▪ 6.67 wt.% C
▪ Stoichiometry for
Fe3C
▪ Iron carbide or
cementite
▪ This phase diagram
eutectoid is in fact Fe-Fe3C

Hypoeutectoid Hypereutectoid Hypoeutectic Hypereutectic

steels cast irons
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Fe-C phase fase Fe-C

Phases in the Fe-C System

-Ferrite (BCC):

 Interstitial solid solution of C in
BCC iron

 Low C concentration, maximum
solubility 0.022 wt.% at 727ºC

 Soft phase

 Density 7.88 g/cm3

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Fe-C phase fase Fe-C

Phases in the Fe-C System

-Austenite (FCC):

 interstitial solid solution of C in

FCC iron

 Maximum solubility of C

2.14 wt.% at 1147 ºC

 Important for phase transitions in

heat treatment of steels

 Not magnetic

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Fe-C phase fase Fe-C

Phases in the Fe-C System

-Ferrite (BCC):

 interstitial solid solution of C in
BCC iron

 The same properties as -Ferrite
but at higher temperatures

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Fe-C phase fase Fe-C

Phases in the Fe-C System

Cementite (Fe3C):

 Intermetallic compound, 6.67 %C
(Fe3C)

 Forms when the solubility limit of
carbon in -Fe is exceeded below
727 ºC

 Hard and brittle

 Metastable compound

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Phases in the Fe-C System

Two-phase regions:

 -Ferrite + Fe3C

Bellow 727 ºC

 -Austenite + Fe3C

Between 727ºC and 1147ºC

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Invariant reactions

Eutectoid reaction (727ºC):

γ (0.76%)   (0.022%) + Fe3C(6.67%)
(pearlite)

Eutectic reaction (1147ºC):

L(4.3%)  γ (2.14%) + Fe3C(6.67%)
(ledeburite)

Peritectic reaction (1493ºC):

δ (0.09%) + L(0.53%)  γ (0.16%)
(austenite)

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Fe-C phase fase Fe-C

Pearlitic (Eutectoid) transformation

Pearlite: Alternating layers (lamellae) of 2 phases: Fe + Fe3C:
Ferrite nucleates on the austenite grain boundary, rejects C which diffuses along
the interface to next layer to form cementite.
-
Grain boundary Carbon diffusion
along the interface
Coarse
pearlite

VE
γ γ
Fine
Pearlite

+
γ Austenite (0.76%C) Ferrite (0.022%C)
Decreasing the pearlitic lamella
Cementite (6.67%C) spacing increases its hardness.
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Eutectoid Steels 𝑪𝟎 = 𝟎. 𝟕𝟔%𝑪
A single microconstituent: Pearlite, formed
alternating layers of 2 phases:

Cementite (Fe3C) Ferrite ()

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Fe-C phase fase Fe-C

Eutectoid Steels 𝑪𝟎 = 𝟎. 𝟕𝟔%𝑪

T > 727 °C (point a)
Phases Present & Composition
Austenite
CγFe= C0= 0.76%C
%γFe= 100%
T < 727 °C (point b)
Phases Present & Composition
Ferrite (α) & Cementite (Fe3C)
CFe − = 0.022%C
CFe3C = 6.67%C
Amount of phases (Weight fractions)
CFe3C − C0 6.67 − 0.76
%Fe − = * 100 = * 100 = 89%
CFe3C − C 6.67 − 0.022
%Fe3C = 100 − 89 = 11%
Microconstituents
Pearlite 6.67 %C
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Hypoeutectoid Steels 𝑪𝟎 < 𝟎. 𝟕𝟔%𝑪

Two microconstituents:
Proeutectoide ferrite Pearlite ( + Fe3C)
or primary (P)

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Hypoeutectoid Steels 𝑪𝟎 < 𝟎. 𝟕𝟔%𝑪

Point c C0 = 0.3%C

Phases Present & Composition
Austenite ()
C = C0 = 0.3%C

Amount of phases (Weight fractions)

W = 100%

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Hypoeutectoid Steels
Point d C0 = 0.3%C

Phases Present & Composition

Ferrite () + Austenite ()

𝐶𝛼 = 0.02%𝐶
C = 0.4%C

Amount of phases (Weight fractions)

S C − C0 0.4 − 0.3
W = 100 =  100 = 100 = 26%
R+S C − C  0.4 − 0.02

R C0 − C  0.3 − 0.02
W = 100 = 100 = 100 = 74%
R+S C − C  0.4 − 0.02

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Fe-C phase fase Fe-C

Hypoeutectoid Steels
Point e C0 = 0.3%C

Phases Present & Composition

Ferrite () + Austenite ()

𝐶𝛼 = 0.02%𝐶
C = 0.76%C

Amount of phases (Weight fractions)

S C − C0 0.76 − 0.3
W = 100 =  100 = 100 = 62%
R+S C − C  0.76 − 0.02

R C0 − C  0.3 − 0.02
W = 100 = 100 = 100 = 38%
R+S C − C  0.76 − 0.02

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Fe-C phase fase Fe-C

Hypoeutectoid Steels
Point f C0 = 0.3%C

Phases Present & Composition
Ferrite () + Cementite (Fe3C)
2 →  ( pro + E ) y Cementite

𝐶𝛼 = 0.02%𝐶 CFe3C = 6.67%C
Amount of phases (Weight fractions)
C Fe3C − C0 6.67 − 0.3
W (total ) = *100 = *100 = 96%
C Fe3C − C 6.67 − 0.022

E 3C − C0
C Fe 0.76 − 0.3
W p = *100 = *100 = 62%
CEFe3C − C 0.76 − 0.022

W E = 96 − 62 = 34% WFe3C = 100 − 96 = 4%

Proeutectoid Ferrite
Microconstituents Pearlite
6.67 %C
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Hypereutectoid Steels 𝑪𝟎 > 𝟎. 𝟕𝟔%𝑪

Two microconstituents:
Proeutectoid
cementite (Fe3C)P Pearlite ( + Fe3C)

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Influence of the alloying elements
γ-stabilizers: Favour the γ phase → A3, A1 → displacing the eutectoid to lower T
at lower %C
Mn, Co, Ni, Cu, Zn, Au

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Influence of the alloying elements
-stabilizers: Favour the  phase → A3→ displacing the eutectoid to higher T at
lower %C

Si, P, Al, Be, Sn, Sb, As,
Ti, Nb, V, Ta, Mo, W, Cr

A3
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Influence of the alloying elements
The presence of other elements in the Fe-C system can influence the
temperature and composition at which the eutectoid reaction occurs.

-stabilizers

γ-stabilizers
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Fe-C phase fase Fe-C

Summary
On the basis of composition, ferrous alloys fall into:
Steels (0.008 wt% C to 2.14 wt% C)
Cast irons (>2.14 wt% C)

Important phases found on the Fe–C phase diagram are
-ferrite (BCC), -austenite (FCC), and the intermetallic compound
cementite (Fe3C).
The microstructural product of an Fe-C alloy of eutectoid composition is pearlite, a
microconstituent consisting of alternating layers of -ferrite and cementite.

The microstructure of alloys having carbon contents less than the eutectoid
(hypoeutectoid steels) are composed of proeutectoid -ferrite phase and pearlite.

The microstructure of alloys having carbon contents higher than the eutectoid
(hypereutectoid steels) are composed of proeutectoid cementite and pearlite.

The amount of proeutectoid (ferrite or cementite) and pearlite microconstituents
can be computed using the lever rule and a tie line.

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