Alloys Steel
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Transcript of Alloys Steel
![Page 1: Alloys Steel](https://reader030.fdocuments.net/reader030/viewer/2022020122/553f3dfd550346786d8b475d/html5/thumbnails/1.jpg)
Alloys & Their Phase DiagramsAlloys & Their Phase Diagrams
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Objectives of the classObjectives of the class
Gibbs phase ruleIntroduction to phase diagram
Practice phase diagramLever rule
Important Observation: One question in the midterm
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Gibbs phase ruleGibbs phase rule
P + F = C +2
P: number of phases (ie, solid, liquid, or gas)C: number of components
F: Degree of freedom
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Simple ExampleSimple ExampleWater:
a) At the triple point:P = 3 (solid, liquid, and gas)
C= 1 (water)P + F = C + 2
F = 0 (no degree of freedom)
b) liquid-solid curveP = 2
2+F = 1 + 2F= 1
One variable (T or P) can be changed
c) LiquidP =1
So F =2Two variables (T and P) can be varied independently
and the system will remains a single phase
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Unlimited SolutibityUnlimited Solutibity
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Limited solubilityLimited solubility
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No SolubilityNo Solubility
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Binary Isomorphous Alloy SystemsBinary Isomorphous Alloy Systems
A mixture of two metals is called a binary alloy and constitutes a two-component system.
Each metallic element in an alloy is called a separate component.
Isomorphous systems contain metals which are completely soluble in each other and have a single type of crystal structure.
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Cu-Ni: A Substitutional Solid SolutionCu-Ni: A Substitutional Solid Solution
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Cu-Ni: Binary Isomorphous Alloy ExampleCu-Ni: Binary Isomorphous Alloy Example
Liquidus line
Solidus line
Tie line
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The Lever RuleThe Lever Rule
Fraction of the solid phase = (Wo – Wl)/(Ws-Wl)
To compute the amount of solid phase:
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Cu-Ni: Cooling CurvesCu-Ni: Cooling Curves
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Cooling curveCooling curve
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Some examplesSome examples
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Binary Eutectic Alloy SystemsBinary Eutectic Alloy Systems
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Eutectic composition:Eutectic composition:
Composition of the phases:Alpha: 19.2% SnBeta: 97.5% Sn
Phases: alpha and beta
Amount of phases:45.5% of alpha: (97.5-61.9)/(97.5-19.2)
54.5% of beta phase
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Example: Point DExample: Point D
Composition of the phases:Alpha: 19.2% SnLiquid: 61.9% Sn
Phases: liquid and alpha
Amount of phases:51% of alpha phase: (61.9-40)/(61.9-19.2)
49% of liquid phase
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Example: Point EExample: Point E
Composition of the phases:Alpha: 19.2% Snbeta: 97.5% Sn
Phases: alpha and beta
Amount of phases:73% of alpha phase: (97.5-40)/(97.5-19.2)
27% of beta phase
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So what? So what?
Soft: eutectic (free flowing): electronic assembyEutetic: from the Greek
easy melting
Plumbers’ solder: pasty used in joints (Romans) and car body fillingHigh-meltingsolder
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A Eutectic Cooling CurveA Eutectic Cooling Curve
Temperature-time cooling curvefor 60% Pb – 40% Sn alloy
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Eutectic MicrostructuresEutectic Microstructures
There are a number of different “morphologies#” for the two phases in a binary eutectic alloy.
Of prime importance is the minimization of the interfacial area between the phases.
The rate of cooling can also have an important effect.
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Eutectic MicrostructuresEutectic MicrostructuresSchematic illustration of the
various eutectic microstructures: (a) lamellar, (b) rodlike, (c) globular, and (d) acicular (or needlelike).
Morphology means the “form”, “shape” or “outward microstructure” of a phase.
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Microstructure evolutionMicrostructure evolution
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Equilibrium Microstructure of Steel AlloysEquilibrium Microstructure of Steel Alloys
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The Iron-Iron Carbide Phase DiagramThe Iron-Iron Carbide Phase Diagram
ferriteBCC iron crystal lattice
AusteniteFCC crystal
CementiteHard and brittle
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Steels and IronsSteels and Irons
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ForgingForging
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ForgingForging
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Plain-Carbon SteelPlain-Carbon Steel
Steel can be defined as an Iron alloy which transforms to Austenite on heating.
A plain-carbon steels has no other major alloying element beside carbon.
When a plain-carbon steel is slowly cooled from the Austenitic range it undergoes the eutectoid transformation.
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Construction steelConstruction steel
Construction steel alloys used for concrete reinforcing bars and structural shapes have been traditionally been 0.1-0.2% C plain-carbon steels with only minor additional elements.
In general these alloys are called Low-alloy Steel and for most purposes they can be considered plain-carbon steel.
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The Iron-Iron Carbide Eutectoid SystemThe Iron-Iron Carbide Eutectoid System
Note: pearlite is not a phase, but a combination of ferrite and cementite
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EutectoidEutectoid
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Eutectoid MicrostructuresEutectoid MicrostructuresJust like the eutectic systems there are a number of different
“morphologies#” for the two phases in a binary eutectic alloy.
The most common morphology for eutectoid areas in the Fe-Fe3C system is lamellar. (This is because most steel is relatively slowly cooled through the eutectoid phase transformation.)
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Evolution of Eutectoid Steel MicrostructureEvolution of Eutectoid Steel Microstructure
Hypoeutectoid Hypereutectoid
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Slow Cooling of Plain-Carbon SteelsSlow Cooling of Plain-Carbon SteelsTransformation of a 0.4% C hypoeutectoid plain-carbon
steel with slow cooling.
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HypoeutectoidHypoeutectoid
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Slow Cooling of Plain-Carbon SteelsSlow Cooling of Plain-Carbon SteelsTransformation of a 1.2% C hypereutectoid plain-carbon steel
with slow cooling.
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HypereutectoidHypereutectoid
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Carbon Steel (90% of the steel production)Carbon Steel (90% of the steel production)
Low alloy steel (up to 6% of chromium, nickel, etc)
Stainless steel (18% chromium and 8% nickel)
Tool steels ( heavy alloyed with chromium, molybdenum, tungsten, vanadium, and cobalt).
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ProblemProblemA 0.45%C hypoeutectoid plain-carbon steel is slowly
cooled from 950 C to a temperature just slightly above 723 C. Calculate the weight percent austenite and weight percent proeutectoid ferrite in this steel.
0.45
0.800.02
Austenite = (0.45-0.02)/(0.80-0.02) = 55.1%
Proeutectoid Ferrite =(0.80-0.45)/(0.8-0.02)
= 44.9
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A 0.45%C hypoeutectoid plain-carbon steel is slowlycooled from 950 C to a temperature just slightlybelow 723 C.
(a)Calculate the weight percent proeutectoid ferrite in this steel.
(b) Calculate the weight percent eutectoid ferrite and the weight percent eutectoid cementite in this steel.
Proeutectoid Ferrite =(0.80-0.45)/(0.8-0.02)=44.9%
Cementite = (0.45-0.02)/(6.67-0.02) = 6.5%
0.45
0.800.02 Total ferrite = (6.67-0.45)/(6.67-0.02) = 93.5%Eutectoid ferrite =
total ferrite – proeutectoid ferrite= 93.5 – 44.9 = 48.6%
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ProblemProblem
A hypoeutectoid steel contains 22.5% eutectoid ferrite. What is the average carbon content?
Total ferrite= proeutectoid ferrite + eutectoid ferrite
(6.67-x)/(6.67-0.02) = (0.80 –x)/(0.8-0.02) + 0.225
X =0.2
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Jominy Hardenability TestJominy Hardenability Test
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Intermediate Phases - Cu-Zn ExampleIntermediate Phases - Cu-Zn Example
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Hypoeutectoid Phase DiagramHypoeutectoid Phase Diagram
If a steel with a composition x% carbon is cooled from the Austenite region at about 770 °C ferrite begins to form. This is called proeutectoid (or pre-eutectoid) ferrite since it forms before the eutectoid temperature.