1. Chapter 11 -
MBA Admission in India
By:
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2. Day 14: Heat treatments of Steel
• Quenching and Tempering Steel (Basic, more
Chapter 11 -
complete discussion later)
• Spheroidizing
• Full Annealing
• Normalizing
• Hardenability (More on the quenching and
tempering process.)
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3. Steels
Low Alloy High Alloy
low carbon
<0.25 wt% C
Med carbon
0.25-0.6 wt% C
high carbon
0.6-1.4 wt% C
plain HSLA plain heat
Name stainless
Additions none Cr,V
treatable plain tool austenitic
Ni, Mo none Cr, Ni
Mo none Cr, V,
Mo, W Cr, Ni, Mo
Example 1010 4310 1040 4340 1095 4190 304
Hardenability 0 + + ++ ++ +++ 0
TS - 0 + ++ + ++ 0
EL + + 0 - - -- ++
Uses auto
struc.
sheet
bridges
towers
press.
vessels
crank
shafts
bolts
hammers
blades
pistons
gears
wear
applic.
wear
applic.
drills
saws
dies
high T
applic.
turbines
furnaces
V. corros.
resistant
increasing strength, cost, decreasing ductility
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Based on data provided in Tables 11.1(b), 11.2(b), 11.3, and 11.4, Callister 7e. Chapter 11 - 3
4. Quenching and Tempering
• We have found that Martensite (M) is very hard,
strong, and brittle. It sees little use as an end
product.
• But, if we reheat to below 727, (250-650) and leave
the M there for a while, it changes into something
with real usefulness. Tempered Martensite. (TM)
• TM is ferrite, with an extremely fine dispersion of
roughly spherical particles of Fe3C. Extremely
strong, but has ductility and toughness. This is
the primo stuff, as far as steel goes.
Chapter 11 -
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5. Chapter 11 -
A Typical Q&T Steel
• We will use Matweb to look over a couple of
steels.
• Note the differences in strength and ductility in a
1060 Steel. The annealed steel with have very
coarse pearlite. The Q&T steel will have very
finely distributed cementite.
Process UTS Yield %EL Hardness
Annealed 90.6 ksi 53.7 ksi 22 88
Q & T 148.7 ksi 98.2 15 99
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6. Chapter 11 -
Spheroidizing
• Strangely, sometimes we would like the steel to
be just as soft and ductile as absolutely possible.
• Why, do you think?
• Pearlite is not the lowest energy arrangement
possible between ferrite and cementite. If heated
to just below the eutectoid temperature, and left
for an extended time, the pearlite layers break
down, and spherical clumps of cementite are
found.
• These spherical clumps are hundreds or even
thousands of times larger that those in TM, and
spaced much further apart. Softest, most duct.
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8. Chapter 11 -
More on Spheroidite
• You have to spend a lot of energy cooking steel.
Spheroidizing is not really used with low carbon
steels, since they are already soft and ductile
enough.
• Spheroidizing is done with the higher carbon
steels, so they will be as ductile as possible for
shaping.
• Spheroidizing is done to improve the
machineability of high carbon steels. Having the
massive cementite regions enhances chip
formation.
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9. Chapter 11 -
Full Anneal
• The idea is to get the soft metal and relieve
stresses. We contrast this anneal with the
“process anneal” associated with CW.
• In the full anneal, we must fully austenitize the
steel. This is followed by a furnace cool, the
slowest cooling rate possible.
• The result is coarse Pearlite mixed with primary
phase. This steel will be close to spheroidite in
its softness and ductility.
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10. Chapter 11 -
Normalizing Steel
• Here we austenitize the steel and then air cool as
opposed to furnace cooling.
• The result is a uniform microstructure, very
uniformly spaced pearlite in equal sized grains
throughout.
• It is stronger and somewhat less ductile than full
anneal.
• Often done after forging to normalize the grain
structure.
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11. Thermal Processing of Metals
• Spheroidize (steels):
Make very soft steels for
good machining. Heat just
below TE & hold for
15-25 h.
• Full Anneal (steels):
Make soft steels for
good forming by heating
to get g, then cool in
furnace to get coarse P.
Chapter 11 -11
Annealing: Heat to Tanneal, then cool slowly.
• Stress Relief: Reduce
stress caused by:
-plastic deformation
-nonuniform cooling
-phase transform.
Types of
Annealing
• Process Anneal:
Negate effect of
cold working by
(recovery/
recrystallization)
Based on discussion in Section 11.7, Callister 7e.
• Normalize (steels):
Deform steel with large
grains, then normalize
to make grains small.
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12. 800
T(°C)
600
10 -1 10 10 3 10 5
Chapter 11 -12
Heat Treatments
a) Annealing
b) Quenching
c)
c) Tempered
Martensite
Adapted from Fig. 10.22, Callister 7e.
time (s)
400
Austenite (stable)
200
P
B
TE
0%
100%
50%
A
A
M + A
M + A
0%
50%
90%
b) a)
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13. Chapter 11 -
Hardenability
• We have seen the advantage of getting
martensite, M. We can temper it, getting TM with
the best combination of ductility and strength.
• But the problem is this: getting M in depth,
instead of just on the surface. We want a steel
where Pearlite formation is relatively sluggish so
we can get it to the cooler regions where M
forms.
• The ability to get M in depth for low cooling rates
is called hardenability.
• Plain carbon steels have poor hardenability.
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14. Jominy Test for Hardenability
• Hardenability not the same as hardness!
Chapter 11 -
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15. Adapted from Fig. 11.11,
Callister 7e. (Fig. 11.11
adapted from A.G. Guy,
Essentials of Materials
Science, McGraw-Hill Book
Company, New York,
1978.)
Chapter 11 -15
Hardenability--Steels
• Ability to form martensite
• Jominy end quench test to measure hardenability.
specimen
(heated to g
phase field)
• Hardness versus distance from the quenched end.
Adapted from Fig. 11.12,
Callister 7e.
24°C water
flat ground
Rockwell C
hardness tests
Hardness, HRC
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16. Why Hardness Changes W/Position
Chapter 11 -16
• The cooling rate varies with position.
distance from quenched end (in)
Adapted from Fig. 11.13, Callister 7e.
(Fig. 11.13 adapted from H. Boyer (Ed.)
Atlas of Isothermal Transformation and
Cooling Transformation Diagrams,
American Society for Metals, 1977, p.
376.)
Hardness, HRC
60
40
20
0 1 2 3
T(°C)
600
400
200
A ® P
M(start)
A ® M
Pearlite
Fine Pearlite
0.1 1 10 100 1000
Time (s)
0
0%
100%
M(finish)
Martensite
Martensite + Pearlite
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17. The Result is Presented in a Curve
Note:
1.Distance from
quenched end
corresponds to a
cooling rate, and a bar
diameter
2.Notice that some
steels drop off more
than others at low
cooling rates. Less
hardenability!
Chapter 11 -
Rank steels in order of
hardenability.
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18. Chapter 11 -
Factors Which Improve
Hardenability
• 1. Austenitic Grain size. The Pearlite will have an
easier time forming if there is a lot of g.b. area.
Hence, having a large austenitic grain size
improves hardenability.
• 2. Adding alloys of various kinds. This impedes
the g P reaction.
TTT diagram of a
molybdenum steel
0.4C 0.2Mo
After Adding
2.0% Mo
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19. Hardenability vs Alloy Composition
100
4340 80
%M
50
4140
8640
5140
shift from
A to B due
to alloying
M(start)
M(90%)
Chapter 11 -19
• Jominy end quench
results, C = 0.4 wt% C
Adapted from Fig. 11.14, Callister 7e.
(Fig. 11.14 adapted from figure furnished
courtesy Republic Steel Corporation.)
• "Alloy Steels"
(4140, 4340, 5140, 8640)
--contain Ni, Cr, Mo
(0.2 to 2wt%)
--these elements shift
the "nose".
--martensite is easier
to form.
Cooling rate (°C/s)
60
Hardness, HRC
40
20
100 10 3 2
1040
0 10 20 30 40 50
Distance from quenched end (mm)
800
T(°C)
600
400
200
010-1 10 103 105
Time (s)
A B
TE
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20. Quenching Medium & Geometry
Chapter 11 -20
• Effect of quenching medium:
Medium
air
oil
water
Severity of Quench
low
moderate
high
Hardness
low
moderate
high
• Effect of geometry:
When surface-to-volume ratio increases:
--cooling rate increases
--hardness increases
Position
center
surface
Cooling rate
low
high
Hardness
low
high
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21. Chapter 11 -21
Ferrous Alloys
Iron containing – Steels - cast irons
Nomenclature AISI & SAE
10xx Plain Carbon Steels
11xx Plain Carbon Steels (resulfurized for machinability)
15xx Mn (10 ~ 20%)
40xx Mo (0.20 ~ 0.30%)
43xx Ni (1.65 - 2.00%), Cr (0.4 - 0.90%), Mo (0.2 - 0.3%)
44xx Mo (0.5%)
where xx is wt% C x 100
example: 1060 steel – plain carbon steel with 0.60 wt% C
Stainless Steel -- >11% Cr
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