Title: Metallography of Rolled Metals
1 Metallography of Deformed, Welded and Surface
Hardened Structures MSE 206-Materials
Characterization I Lecture-8
2Metal Fabrication Methods
FORMING
Forging (wrenches, crankshafts)
Rolling (I-beams, rails)
often at elev. T
Extrusion (rods, tubing)
Drawing (rods, wire, tubing)
3Metal Fabrication Methods Forming Methods
1-Forging
A bulk deformation process in which the workpiece
(preform) is squeezed between two opposing dies,
thus the shape of the dies is imparted on the
work part. It can be done cold or hot.
4Metal Fabrication Methods Forming Methods
2-Rolling
A bulk deformation process in which the thickness
of the work part is reduced by compressive forces
exerted by two opposing rolls.
5Metal Fabrication Methods Forming Methods
3-Extrusion
- Extrusion is a bulk deformation process in which
material is forced to flow through a
shape-forming die. - In extrusion, work part is pushed to flow through
die opening rather than pulling. - Extrusion can be cold or hot.
- Cross-section of the part must be uniform along
its extruded length.
6Metal Fabrication Methods Casting
CASTING
Die Casting (high volume, low T alloys)
Sand Casting (large parts, e.g.,auto
engine blocks)
Continuous Casting (simple slab shapes)
Investment Casting (low volume, complex
shapes e.g., jewelry, turbine blades)
plaster die formed around wax prototype
7Metal Fabrication Methods Casting
Process in which molten metal flows by gravity
or other force into a mold where it solidifies
in the shape of the mold cavity. Term casting
also denotes the part made in the process. 1.
Melt the metal 2. Pour the metal in cavity 3.
Let the metal freeze
8Metal Fabrication Methods Joining
JOINING
Welding (when one large part is
impractical)
Heat affected zone (region in which the
microstructure has been changed).
9Metal Fabrication Methods Forming
Temperature of Forming
- When the deformation is achieved at a temperature
above the recrystallization temperature (?0.5Tm) - the process is called hot working
- otherwise, it is cold working
- For most forming techniques, both hot and cold
working procedures are possible.
10Metal Fabrication Methods Cold Working
- Strength is increased considerably due to strain
hardening. -
- Ductility is decreased.
- Quality of the surface is higher when compared to
hot worked metals. - Better control of the dimensions of the finished
piece is possible.
11Effect of Cold Rolling On Grain Shape
Metal Fabrication Methods Cold Working
- As a result of cold working, the equiaxed grains
of the metal are deformed into elongated grains - The elongation is along the direction of applied
stress
12Effect of Reduction by Cold Rolling on
hypoeutectoid Steel
Metal Fabrication Methods Cold Working
13Annealing after cold working
- Annealing is a heat treatment to negate the
effects of cold work and increase the ductility
of a strain hardened metal. - Strain hardening is a result of increased
dislocation interactions due to increased
dislocation density. - Heating of a strain hardened metal for annealing
results in - 1-Recovery (dislocation and vacancy annihilation)
- 2-Recrystallization (nucleation and growth of
strain and dislocation free grains)
14Annealing after cold working
Cold rolled and annealed AISI 1010 steel
(a) (b) (c)
- Cold rolled, 90 deformation. Grains elongated
along the rolling axis can not be differentiated
easily in the optical microscope - Annealed at 650ºC for 5 min, recrystallized
10-40. New dislocation free ferrite grains are
nucleating and growing. - Further annealed, recrystallized 80.
Recrystallized ferrite grains can be seen clearly.
15Annealed Structures of Non-ferrous Alloys
a) Fully annealed homogeneous hexagonal equiaxed
grains. b) Cold worked metal with flattened
grains. c) Annealed after cold working showing
twinned grains. d) Cold worked again, after
annealing, showing distorted twin lines and
strain lines in the grains.
16Effect of Annealing Temperature
Annealed Structures of Non-ferrous Alloys
a-brass (70Cu-30Zn) -- Cold worked and annealed at
(a) (b)
(c)
450 ºC 550 ºC
750 ºC
17Annealed Structures of Non-ferrous Alloys
Annealing twins in a-brass
18Metal Fabrication Methods Hot Working
- In Hot Working, which is carried out at
temperatures over the recrystallization
temperature, Large deformations and successive
operations are possible because the dislocations
(hardening) generated by deformation are
simultaneously annihilated by dynamical recovery
and recrystallization.
- Deformation energy requirements are less compared
to those for cold working. - Surface oxidation may cause loss of material and
poor surface finish.
19Banding in Hot Worked Alloys
Metal Fabrication Methods Hot Working
- During solidification of steels elemental
segregation of C, S, P, Mn may occur. - When such steels are hot-rolled, elongated bands
of different carbon and mangenese content occurs. - Bands of ferrite and pearlite forms along the
direction of rolling.
20Banded Structures in Steel
Metal Fabrication Methods Hot Working
21Surface Hardening
Surface Hardening Used to obtain hard wear
resistant surface without effecting the
relatively soft, tough interior.
Case Hard wear resistant surface Core
Relatively soft, tough inside
- Surface hardening is usefull in parts such as
cam or ring gear that must have a very hard
surface to resist wear, along with a tough
interior to resist the impact.
22Surface Hardening
Surface Hardening of steels
Layer addition Substrate treatment
Hardfacing - Fusion hardfacing - Thermal spray Coatings - Electrochemical plating - Chemical vapor deposition (electroless plating) - Thin films (physical vapor deposition, sputtering, ion plating) - Ion mixing Diffusion Methods - Carburizing - Nitriding - Carbonitriding and cyaniding - Nitrocarburizing - Boriding - Titanium-carbon diffusion - Toyota diffusion process Selective hardening methods - Flame hardening - Induction hardening - Laser hardening - Electron beam hardening - Ion implantation - Selective carburizing and nitriding - Use of arc lamps
23Surface Hardening
- Surface is hardened to
- increase wear resistance
- increase surface strength for load carrying
capacity (crush resistance) - impart favorable residual compressive stresses
- improve fatigue resistance
- produce tough core for resistance to impact
Some of the surface hardening methods
Carburizing Nitriding Cyaniding and
carbonitriding Flame hardening Induction
hardening
Diffusion methods Change the chemical composition
Selective hardening methods dont change the
chemical composition. The steel must be capable
of being hardened.
24Carburizing
Surface Hardening
- In the austenic temperatures, carbon is
introduced to the surface of a low carbon steel
component by diffusion to increase the surface
carbon content and produce a hard martensitic
surface layer after quenching. - Traditionally, the carbon is supplied from
- (a) hydrocarbon gas atmosphere
- (b) coke packed around
- (c) carburizing salt bath.
Case depth K vDt
25Surface Hardening
Gas Carburizing
- The steel is heated in contact with CO and/or
hydrocarbon which is readily decomposed at the
carburizing temperature.
- Methane
- Propane
- Natural Gas
- Vaporized fluid hydrocarbon
Hydrocarbon gas
The commercial practice is to use a carrier gas,
such as obtained from an endothermic generator
and enrich it with one of the hydrocarbon gas.
- High surcafe carbon concentration may be
decreased by turning of the gas and keeping the
samples in furnace for a period of time.
26Nitriding
Surface Hardening
- Nitrogen is introduced to the surface of a
special alloy steel (with Al and Cr) component by
diffusion to form alloy nitride precipitates to
produce a hard surface layer. It is done at
around 525C and since hardening is by
precipitates rather than martensite quenching is
not necessary. - Traditionally, nitrogen is supplied from amonia
gas atmosphere or cyanide bath.
27Flame Hardening
Surface Hardening
- In Flame hardening a thin surface shell of medium
carbon steel or cast iron is heated rapidly to
austenite by an intense high temperature flame of
propane and oxygen gas mixture, then quickly
quenched to obtain martensite of high hardness.
- In flame hardening chemical composition of the
steel doesnt change
28Induction Hardening
Surface Hardening
- Surface of the part is heated very fast by
induction heating and then quenched. Part is put
in a work coil composed of several turns of water
cooled copper. By passing current through this
coil, an eddy current is induced on the surface
of the part, which heats the surface. Then the
part with the austenitized surface is quenched by
using water jets.
- As in flame hardening, chemical composition of
the steel doesnt change in induction hardening
29- Instead of carburizing, induction hardening etc.
sometimes metals are coated with hard ceramics
such as TiN, TiAlN, CrN to increase the wear
resistance of the part
30Joining Welding
- A technique for joining metals in which actual
melting of the pieces to be joined occurs in the
vicinity of the bond. A filler material may be
used to facilitate the process. - Welding is very similar to casting since it also
consists of melting and solidification of the
metal -
31Joining Welding
- Weld Root Dendritic microstructures may be
observed. - HAZ (Heat Affected Zone) Change in grain size
may be observed - Parent Material Welding has no effect on the
microstructure of this region
32Joining Welding
HAZ
After welding
Before welding
Hypoeutectoid steel
(a) Before welding, parent metal consists of a
pearlitic and ferritic matrix. (b) In the regions
exposed to high temperatures (HAZ), pearlite
loses its lamellar morphology, the layers break
up leading to a structure known as divorced
pearlite.
33Joining Welding
HAZ
- Pointed edged widmanstatten ferrites form on
grain boundaries and grow into the grains. Black
regions are unresolved pearlitic areas.
34Joining Welding
Fusion Zone
- The upper left part is the parent metal, lower
right part belongs to the filler material.
35Joining Welding
Weld zone
- Filler materials generally contain very low
amounts of carbon, therefore only ferrite forms
upon solidification. The structure is directly
solidified from the liquid phase, resulting in a
dendritic morphology.
36Welding Discontinuities
Joining Welding
- Cold Cracking
- Hot Cracking
- Porosity in Weld regions
- Slag and Inclusions