Post on 29-Mar-2015
ISSUES TO ADDRESS...• Transforming one phase into another takes time.
• How does the rate of transformation depend on time and T ?• How can we slow down the transformation so that we can engineer non-equilibrium structures?• Are there other means to improve mechanical behavior?
Feg
(Austenite)
Eutectoid transformation
C FCC
Fe3C(cementite)
a (ferrite)
+
(BCC)
Chapter 10: Phase Transformations – Considering Kinetic and Heat Treatment
Nucleation – nuclei (like biological seeds) act as
template to grow crystals– for nuclei to form, the rate of addition of
atoms to any nucleus must be faster than rate of loss
– once nucleated, the “seed” must grow until they reach the predicted equilibrium
Phase Transformations
Phase Transformations
Driving force to nucleate increases as we increase T– supercooling (eutectic, eutectoid)– superheating (peritectic)
• With a Small amount of supercooling few nuclei - large crystals
• With a Large amount of supercooling rapid nucleation - many nuclei, small crystals
Solidification: Nucleation Processes
• Homogeneous nucleation – nuclei form in the bulk of liquid metal (as
“native chemistry”)– requires sufficient supercooling (typically 80-
300°C max)
• Heterogeneous nucleation– much easier since stable “nucleus” is already
present (they are non-native chemically)• Could be wall of mold or impurities in the liquid
phase– allows solidification with only minimal
supercooling (0.1-10ºC)
r* = critical nucleus: nuclei < r* shrink; nuclei>r* grow (to reduce energy)
Homogeneous Nucleation & Energy Effects
DGT = Total Free Energy = DGS + DGV
Surface Free Energy- destabilizes the nuclei (it takes energy to make an interface)
24 rGS
g = surface tension
Volume (Bulk) Free Energy – stabilizes the nuclei (releases energy)
GrGV3
3
4
volume unit
energy free volume G
Solidification
r* decreases as T increases
For typical T r* is around 100Å (10 nm)
TH
Tr
S
m
2
*
Note: HS is a strong function of T is a weak function of T
HS = latent heat of solidification
Tm = melting temperature
g = surface free energy
DT = Tm - T = supercooling
r* = critical radius
Rate of Phase Transformations
Kinetics - measures approach to equilibrium vs. time
• Hold temperature constant & measure conversion vs. time– How is the amount of conversion measured?
• X-ray diffraction – have to do many samples• electrical conductivity – follows a single sample• sound waves (insitu ultrasonic) – follows a single
sample
Thus, the rate of nucleation is a product of two curves that represent two opposing factors (instability and diffusivity).
Rate of Phase Transformation
– Modeled by the Avrami Rate Equation:
t0.5
All out of material – “done!”
Fixed Temp.
maximum rate reached – now amount unconverted decreases so rate slows
rate increases as surface area increases & nuclei grow
Log Time
1nkty e
Avrami EquationAvrami rate equation → y = 1- exp (-ktn)
k & n are fit for any specific sample
• By convention we define: r = 1 / t0.5 as “the rate of transformation” – it is simply the inverse of the time to complete half of the transformation
• The initial slow rate can be attributed to the time required for a significant number of nuclei of the new phase to form and begin growing.
• During the intermediate period the transformation is rapid as the nuclei grow into particles and consume the old phase while nuclei continue to form in the remaining parent phase.
• Once the transformation begins to near completion there is little untransformed material for nuclei to form in and the production of new particles begins to slow. Further, the particles already existing begin to touch one another, forming a boundary where growth stops.
Rate of Phase Transformations
• In general, rate increases as T
r = 1/t0.5 = A e -Q/RT
– R = gas constant– T = temperature (K) (higher causes higher rate too)– A = ‘preexponential’ rate factor– Q = activation energy
• r is often small so equilibrium is not possible!
Arrhenius expression
adapted from B.F. Decker and D. Harker, "Recrystallization in Rolled Copper", Trans AIME, 188, 1950, p. 888.
135C 119C 113C 102C 88C 43C
1 10 102 104
Transformations & Undercooling
• M. Eng. Can make it occur at: ...727ºC (cool it slowly)...below 727ºC (“supercool” or “Undercool” it!)
• Eutectoid transf. (Fe-C System): g Þ a + Fe3C0.76 wt% C
0.022 wt% C6.7 wt% C
Fe 3
C (
cem
entit
e)
1600
1400
1200
1000
800
600
4000 1 2 3 4 5 6 6.7
L
g(austenite)
g+L
g +Fe3C
a +Fe3C
L+Fe3C
d
(Fe) Co , wt%C
1148°C
T(°C)
aferrite
727°C
Eutectoid:Equil. Cooling: Ttransf. = 727ºC
DT
Undercooling by DTtransf. < 727C
0.7
6
0.0
22
adapted from Binary Alloy Phase Diagrams, 2nd ed., Vol. 1, T.B. Massalski (Ed.-in-Chief), ASM International, Materials Park, OH, 1990
Eutectoid Transformation Rate
Coarse pearlite formed at higher T - softer
Fine pearlite formed at low T - harder
Diffusive flow of C needed
a
ag g
a
• Growth of pearlite from austenite:
Adapted from Fig. 9.15, Callister 7e.
gaaaa
a
a
pearlite growth direction
Austenite (g)grain boundary
cementite (Fe3C)
Ferrite (a)
g
• Recrystallization rate increases with DT.
52°C (675˚C)
0
50
y (%
pea
rlite
)127°C
(600 ˚C)77°C
100
• Reaction rate is a result of nucleation and growth of crystals.
• Examples from previous slide:
Nucleation and Growth
T: just below TE
Nucleation rate low
Growth rate high
g
pearlite colony
T: moderately below TE
g
Nucleation rate med
Growth rate med.
Nucleation rate high
T: way below TE
g
Growth rate low
The ideas of “reality” and the “ideal” meet in the Material Engineering’s Transformation
Curves
adapted from H. Boyer (Ed.) Atlas of Isothermal Transformation and Cooling Transformation Diagrams, American Society for Metals, 1977, p. 369.
Isothermal Transformation (TTT) Diagrams
• Fe-C system, Co = 0.76 wt% C• Transformation at T = 675°C.
100
50
01 102 104
T = 675°C
y,
% tr
ansf
orm
ed
time (s)
400
500
600
700
1 10 102 103 104 105
0%pearlite
100%
50%
Austenite (stable) TE (727C)Austenite (unstable)
Pearlite
T(°C)
time (s)
isothermal transformation at 675°C
• Eutectoid composition, Co = 0.76 wt% C• Begin at T > 727°C• Rapidly cool to 625°C and hold isothermally.
adapted from H. Boyer (Ed.) Atlas of Isothermal Transformation and Cooling Transformation Diagrams, American Society for Metals, 1997, p. 28.
Effect of Cooling History in Fe-C System
400
500
600
700
0%pearlite
100%
50%
Austenite (stable)TE (727C)
Austenite (unstable)
Pearlite
T(°C)
1 10 102 103 104 105
time (s)
g g
g
g g
g
Transformations with Proeutectoid Materials
Hypereutectoid composition – proeutectoid cementite
a
CO = 1.13 wt% C
TE (727°C)
T(°C)
time (s)
A
A
A+
C
P
1 10 102 103 104
500
700
900
600
800
A+
P
Adapted from Fig. 10.16, Callister 7e.
Adapted from Fig. 9.24, Callister 7e.
Fe 3
C (
cem
entit
e)
1600
1400
1200
1000
800
600
4000 1 2 3 4 5 6 6.7
L
g(austenite)
g+L
g +Fe3C
a +Fe3C
L+Fe3C
d
(Fe) Co , wt%C
T(°C)
727°CDT
0.7
6
0.0
22
1.13
Non-Equilibrium Transformation Products in Fe-C
• Bainite: --a lathes (strips) with long
rods of Fe3C --diffusion controlled.• Isothermal Transf. Diagram
adapted from H. Boyer (Ed.) Atlas of Isothermal Transformation and Cooling Transformation Diagrams, American Society for Metals, 1997, p. 28.
from Metals Handbook, 8th ed., Vol. 8, Metallography, Structures, and Phase Diagrams, American Society for Metals, Materials Park, OH, 1973.)
Fe3C
(cementite)
5 mm
a (ferrite)
10 103 105
time (s)10-1
400
600
800
T(°C)Austenite (stable)
200
P
B
TE
0%
100%
50%
pearlite/bainite boundary
A
A
100% bainite
100% pearlite
From: George Krauss, Steels: Processing, Structure, and Performance, ASM International, 2006.
TTT Curves showing the Bainite Transformation (a) Plain Carbon Steels; (b) Alloy Steel w/ distinct
Bainite “Nose”
• Martensite: --g(FCC) to Martensite (BCT)
courtesy United States Steel Corporation.
• Isothermal Transf. Diagram
• g to M transformation.. -- is rapid! -- % transf. depends on T only.
Martensite: Fe-C System
Martensite needlesAustenite
60 m
10 103 105 time (s)10-1
400
600
800
T(°C)Austenite (stable)
200
P
B
TE
0%
100%50%
A
A
M + AM + A
M + A
0%50%90%
xx x
xx
xpotential C atom sites
Fe atom sites
(involves single atom jumps)
Transformation to Martensite
Martensite formation requires that the steel be subject to a minimum – Critical – Cooling Rate (this value is ‘TTT’ or ‘CCT’ chart dependent for alloy of interest)
For most alloys it indicates a quench into a RT oil or water bath
(FCC) (BCC) + Fe3C
Martensite Formation
slow cooling
tempering
quench
M (BCT)
M = martensite is body centered tetragonal (BCT)
Diffusionless transformation BCT if C > 0.15 wt%
BCT few slip planes hard, brittle
Martensite Transformation Crystallography: FCC Austenite to BCT Martensite
From: George Krauss, Steels: Processing, Structure, and Performance, ASM International, 2006.
Austenite to Martensite: Size Issues and Material Response
From: George Krauss, Steels: Processing, Structure, and Performance, ASM International, 2006.
• Spheroidite: --a grains with spherical Fe3C --diffusion dependent. --heat bainite or pearlite for long times (below the AC1
critical temperature) --driven by a reduction in interfacial area of Carbide
Spheroidite: Fe-C System
(Fig. 10.19 copyright United States Steel Corporation, 1971.)
60 m
a(ferrite)
(cementite)
Fe3C
Phase Transformations of Alloys
Effect of adding other elementsChange transition temp.
Cr, Ni, Mo, Si, Mn
retard + Fe3C
transformation delaying the time to entering the diffusion controlled transformation reactions – thus promoting “Hardenability’ or Martensite development
Continuous Cooling Transformations (CCT)
• Isothermal Transformations are “Costly” requiring careful “gymnastics” with heated (and cooling) products
• CC Transformations change the observed behavior concerning transformation – With Plain Carbon Steels when cooled
“continuously” we find that the Bainite Transformation is suppress(see Figure 10.26)
Cooling CurvePlot:
temp vs. time
CCT for Eutectoid Steel
Figure: 10-26
CCT for Eutectoid Steel
Alloy Steel CCT Curve – again note distinct Bainite Nose
Adapted from Fig. 10.23, Callister 7e.
Dynamic Phase Transformations
On the isothermal transformation diagram for 0.45 wt% C Fe-C alloy, sketch and label the time-temperature paths to produce the following microstructures:a) 42% proeutectoid ferrite and 58% coarse
pearlite
b) 50% fine pearlite and 50% bainite
c) 100% martensite
d) 50% martensite and 50% austenite
A + B
A + P
A + aA
BP
A50%
0
200
400
600
800
0.1 10 103 105
time (s)
M (start)M (50%)M (90%)
Example Problem for Co = 0.45 wt%
a) 42% proeutectoid ferrite and 58% coarse pearlite
first make ferrite
then pearlite
coarse pearlite
higher T
Adapted from Fig. 10.29,Callister 5e.
T (°C)
b) 50% fine pearlite and 50% bainite
first make pearlite
then bainite
fine pearlite
lower T
T (°C)
A + B
A + P
A + aA
BP
A50%
0
200
400
600
800
0.1 10 103 105
time (s)
M (start)M (50%)M (90%)
Example Problem for Co = 0.45 wt%
Adapted from Fig. 10.29, Callister 5e.
NOTE: This “2nd step” is sometimes referred to as an “Austempering” step, quenching into a heated salt bath held at the temperature of need
Example Problem for Co = 0.45 wt%
c) 100 % martensite: quench @ 380C/s {(850-600)/.7s}
Adapted from Fig. 10.29, Callister 5e.
d)
A + B
A + P
A + aA
BP
A50%
0
200
400
600
800
0.1 10 103 105
time (s)
M (start)M (50%)M (90%)
c)
T (°C)
d) 50%martensite/50%(retained) austenite
CT for CrMo Med-carbon steel
Hardness of cooled samples at various cooling rates in bubbles -- Dashed lines are IT solid lines are CT regions
Tempering Martensite• reduces brittleness of martensite,• reduces internal stress caused by quenching.
copyright by United States Steel Corporation, 1971.
• decreases TS, YS but increases %RA• produces extremely small Fe3C particles surrounded by a.
from Fig. furnished courtesy of Republic Steel Corporation.) 9
mm
YS(MPa)TS(MPa)
800
1000
1200
1400
1600
1800
30
40
50
60
200 400 600Tempering T (°C)
%RA
TS
YS
%RA
The microstructure of tempered martensite, although an equilibrium mixture of α-Fe and Fe3C, differs from those for pearlite and bainite. This micrograph produced in a scanning electron microscope (SEM) shows carbide clusters in relief above an etched ferrite. (From ASM Handbook, Vol. 9: Metallography and Microstructures, ASM International, Materials Park, OH, 2004.)
Temper Martensite Embrittlement – an issue in Certain Steels
Suspected to be due to the deposition of very fine carbides during 2nd and 3rd phase tempering along original austenite G. B. from the transformation of retained austenite,
From: George Krauss, Steels: Processing, Structure, and Performance, ASM International, 2006.
Increasing Strength and Hardness of Alloy involves some Heat Treatment
• The effect of quenching in steels is determined by the Jominey End Quench Test
• Precipitation Hardness is a method used for may alloy systems (mostly Non-Ferrous ones)
• Grain Size control is also an important consideration – which can be controlled by annealing processes
• Recovery after cold work (cold work can also increase strength of alloys)
• Recrystalization• Grain Growth
Schematic illustration of the Jominy end-quench test for hardenability. (After W. T. Lankford et al., Eds., The Making, Shaping, and Treating of Steel, 10th ed., United States Steel, Pittsburgh, PA, 1985. Copyright 1985 by United States Steel Corporation.)
Hardenability--Steels• Ability to form martensite• Jominy end quench test to measure hardenability.
• Hardness versus distance from the quenched end.
(adapted from A.G. Guy, Essentials of Materials Science, McGraw-Hill Book Company, New York, 1978.)
24°C water
specimen (heated to g phase field)
flat ground
Rockwell Chardness tests
Har
dnes
s, H
RC
Distance from quenched end
Figure 10.22 The cooling rate for the Jominy bar (see Figure 10.21) varies along its length. This curve applies to virtually all carbon and low-alloy steels. (After L. H. Van Vlack, Elements of Materials Science and Engineering, 4th ed., Addison-Wesley Publishing Co., Inc., Reading, MA, 1980.)
Figure 10.23 Variation in hardness along a typical Jominy bar. (From W. T. Lankford et al., Eds., The Making, Shaping, and Treating of Steel, 10th ed., United States Steel, Pittsburgh, PA, 1985. Copyright 1985 by United States Steel Corporation.)
• The cooling rate varies with position.
(adapted from H. Boyer (Ed.) Atlas of Isothermal Transformation and Cooling Transformation Diagrams, American Society for Metals, 1977, p. 376.)
Why Hardness Changes W/Position
distance from quenched end (in)Ha
rdn
ess
, H
RC
20
40
60
0 1 2 3
600
400
200A ® M
A ®
P
0.1 1 10 100 1000
T(°C)
M(start)
Time (s)
0
0%100%
M(finish) Martensite
Martensite + Pearlite
Fine Pearlite
Pearlite
Hardenability vs Alloy Composition• Jominy end quench results, C = 0.4 wt% C
• "Alloy Steels" (4140, 4340, 5140, 8640) --contain Ni, Cr, Mo (0.2 to 2wt%) --these elements shift the "nose". --martensite is easier to form.
(adapted from figure furnished courtesy Republic Steel Corporation.)
Cooling rate (°C/s)
Har
dne
ss, H
RC
20
40
60
100 20 30 40 50Distance from quenched end (mm)
210100 3
4140
8640
5140
1040
50
80
100
%M4340
T(°C)
10-1 10 103 1050
200
400
600
800
Time (s)
M(start)M(90%)
shift from A to B due to alloying
BA
TE
Figure 10.24 Hardenability curves for various steels with the same carbon content (0.40 wt %) and various alloy contents. The codes designating the alloy compositions are defined in Table 11.1. (From W. T. Lankford et al., Eds., The Making, Shaping, and Treating of Steel, 10th ed., United States Steel, Pittsburgh, PA, 1985. Copyright 1985 by United States Steel Corporation.)
• Effect of quenching medium:
Mediumairoil
water
Severity of Quenchlow
moderatehigh
Hardnesslow
moderatehigh
• Effect of geometry: When surface-to-volume ratio increases: --cooling rate increases --hardness increases
Positioncentersurface
Cooling ratelowhigh
Hardnesslowhigh
Quenching Medium & Geometry
0 10 20 30 40 50wt% Cu
L+La
+a q q
+L
300
400
500
600
700
(Al)
T(°C)
composition range needed for precipitation hardening
CuAl2
A
Adapted from Fig. 11.24, Callister 7e. (Fig. 11.24 adapted from J.L. Murray, International Metals Review 30, p.5, 1985.)
Precipitation Hardening• Particles impede dislocations.• Ex: Al-Cu system• Procedure:
--Pt B: quench to room temp.--Pt C: reheat to nucleate small q crystals within a crystals.
• Other precipitation systems: • Cu-Be • Cu-Sn • Mg-Al
Temp.
Time
--Pt A: solution heat treat (get a solid solution)
Pt A (sol’n heat treat)
B
Pt B
C
Pt C (precipitate ) Consider: 17-4 PH St. Steel and Ni-Superalloys too!
Figure 10.25 Coarse precipitates form at grain boundaries in an Al–Cu (4.5 wt %) alloy when slowly cooled from the single-phase (κ) region of the phase diagram to the two-phase (θ + κ) region. These isolated precipitates do little to affect alloy hardness.
Figure 10.26 By quenching and then reheating an Al–Cu (4.5 wt %) alloy, a fine dispersion of precipitates forms within the κ grains. These precipitates are effective in hindering dislocation motion and, consequently, increasing alloy hardness (and strength). This process is known as precipitation hardening, or age hardening.
Figure 10.27 (a) By extending the reheat step, precipitates coalesce and become less effective in hardening the alloy. The result is referred to as overaging. (b) The variation in hardness with the length of the reheat step (aging time).
Figure 10.28 (a) Schematic illustration of the crystalline geometry of a Guinier–Preston (G.P.) zone. This structure is most effective for precipitation hardening and is the structure developed at the hardness maximum shown in Figure 10.27b. Note the coherent interfaces lengthwise along the precipitate. The precipitate is approximately 15 nm × 150 nm.
(From H. W. Hayden, W. G. Moffatt, and J. Wulff, The Structure and Properties of Materials, Vol. 3: Mechanical Behavior, John Wiley & Sons, Inc., NY, 1965.) (b) Transmission electron micrograph of G.P. zones at 720,000×. (From ASM Handbook, Vol. 9: Metallography and Microstructures, ASM International, Materials Park, OH, 2004.)
Figure 10.30 Annealing can involve the complete recrystallization and subsequent grain growth of a cold-worked microstructure. (a) A cold-worked brass (deformed through rollers such that the cross-sectional area of the part was reduced by one-third). (b) After 3 s at 580°C, new grains appear. (c) After 4 s at 580°C, many more new grains are present.
(d) After 8 s at 580°C, complete recrystallization has occurred. (e) After 1 h at 580°C, substantial grain growth has occurred. The driving force for this growth is the reduction of high-energy grain boundaries. The predominant reduction in hardness for this overall process had occurred by step (d)
All micrographs have a magnification of 75×. (Courtesy of J. E. Burke, General Electric Company, Schenectady, NY.)
Figure 10.31 The sharp drop in hardness identifies the recrystallization temperature as ~290°C for the alloy C26000, “cartridge brass.” (From Metals Handbook, 9th ed., Vol. 4, American Society for Metals, Metals Park, OH, 1981.)
Recrystallization Temperature, TR
TR = recrystallization temperature = point of highest rate of property change1. TR 0.3-0.6 Tm (K)
2. Due to diffusion annealing time TR = f(t) shorter annealing time => higher TR
3. Higher %CW => lower TR – strain hardening
4. Pure metals lower TR due to easier dislocation movements
Figure 10.32 Recrystallization temperature versus melting points for various metals. This plot is a graphic demonstration of the rule of thumb that atomic mobility is sufficient to affect mechanical properties above approximately 1/3 to 1/2 Tm on an absolute temperature scale.
(From L. H. Van Vlack, Elements of Materials Science and Engineering, 3rd ed., Addison-Wesley Publishing Co., Inc., Reading, MA, 1975.)
Figure 10.33 For this cold-worked brass alloy, the recrystallization temperature drops slightly with increasing degrees of cold work.
(From L. H. Van Vlack, Elements of Materials Science and Engineering, 4th ed., Addison-Wesley Publishing Co., Inc., Reading, MA, 1980.)
• At longer times, larger grains consume smaller ones. • Why? Grain boundary area (and therefore energy) is reduced.
After 8 s,580ºC
After 15 min,580ºC
0.6 mm 0.6 mm
Adapted from Fig. 7.21 (d),(e), Callister 7e. (Fig. 7.21 (d),(e) are courtesy of J.E. Burke, General Electric Company.)
Grain Growth
• Empirical Relation:
Ktdd no
n
coefficient dependent on material & Temp.
grain dia. At time t.
elapsed timeExponent is typ. 2
This is: Ostwald Ripening
Figure 10.34 Schematic illustration of the effect of annealing temperature on the strength and ductility of a brass alloy shows that most of the softening of the alloy occurs during the recrystallization stage.
(After G. Sachs and K. R. Van Horn, Practical Metallurgy: Applied Physical Metallurgy and the Industrial Processing of Ferrous and Nonferrous Metals and Alloys, American Society for Metals, Cleveland, OH, 1940.)
Figure 10.29 Examples of cold-working operations: (a) cold-rolling a bar or sheet and (b) cold-drawing a wire. Note in these schematic illustrations that the reduction in area caused by the cold-working operation is associated with a preferred orientation of the grain structure.
We can then find that the “cold working of an alloy” is an effect tool for improving performance –
• if done properly!– so as not to cause the material to exceed its
% EL which was a fracture deformation limit as we saw earlier
– If we impose appropriate intermediate recrystalization (and maybe even grain growth steps)
– Finish with a cold working step to achieve the desired hardness and finished size
Coldwork Hardening Example
A cylindrical rod of brass originally 0.40 in (10.2 mm) in diameter is to be cold worked by drawing. The circular cross section will be maintained during deformation. A cold-worked tensile strength in excess of 55,000 psi (380 MPa) and a ductility of at least 15 %EL are desired. Further more, the final diameter must be 0.30 in (7.6 mm). Explain how this may be accomplished.
Coldwork Calculations Solution
If we directly draw to the final diameter what happens?
%843100 x 400
3001100 x
4
41
100 1100 x %
2
2
2
..
.
D
D
xA
A
A
AACW
o
f
o
f
o
fo
Do = 0.40 in
BrassCold Work
Df = 0.30 in
Coldwork Calc Solution: Cont.
• For %CW = 43.8%
540420
– y = 420 MPa– TS = 540 MPa > 380 MPa
6
– %EL = 6 < 15• This doesn’t satisfy criteria…… what can we do?
Coldwork Calc Solution: Cont.
Adapted from Fig. 7.19, Callister 7e.
380
12
15
27
For %EL > 15
For TS > 380 MPa > 12 %CW
< 27 %CW
our working range is limited to %CW = 12 – 27%
This process Needs an Intermediate Recrystallization
i.e.: Cold draw-anneal-cold draw again• For objective we need a cold work of %CW 12-27
– We’ll use %CW = 20• Diameter after first cold draw (before 2nd cold draw)
– must be calculated as follows:2 2
2 2
2 22 2
%% 1 100 1
100f f
s s
D D CWCW x
D D
0.52
2
%1
100f
s
D CW
D
22 0.5
%1
100
fs
DD
CW
0.5
1 2
200.30 1 0.335 in
100f sD D
Intermediate diameter =
Summary:
1. Initial Cold work D01= 0.40 in Df1 = 0.335 in
2. Anneal above TR Ds2 = Df1
3. Secondary Cold work Ds2= 0.335 in Df 2 =0.30 in
Therefore, we have met all requirements
Coldwork Calculations Solution
20100 3350
301%
2
2
x
.
.CW
24%
MPa 400
MPa 340
EL
TSy
%CW1 10.335
0.4
2
x 100 30