penggunaan tembaga pada baja nano
TRANSCRIPT
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Utilization of Cu in Ferrous Utilization of Cu in Ferrous MaterialsMaterials
Syarif JunaidiSyarif JunaidiDept. Mechanical & Materials Eng. Dept. Mechanical & Materials Eng.
National University of MalaysiaNational University of Malaysia
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Presentation content
1. Introduction2. Objectives3. Strengthening Mechanism4. Effect of Cu in solid-solution5. Advantage of Cu nanoparticles6. Combination of nano steel (ultra fine grained
steel) and Cu nanoparticles7. Summary
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• In Japan, the amount of steel scraps reached 1billion ton (2000), on the other hand, Japan’s steel production : 100million ton/year. (Japan has “natural resource” of steel for 10 years)
• The recycling of steel scraps is retarded because the scraps are contaminated by Cu which is difficult to be eliminated.
• Accumulation of the scraps becomes national problem in Japan.
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Does Cu have advantage?Does Cu have advantage? (Fe-Cu binary alloy)(Fe-Cu binary alloy)
Fe-Cu phase diagram is similar to Fe-C phase diagram
0
wide single phase
wide single phase
•No intermetallic phase•Pearlitic structure or fine second phase•Exhibit martensitic transformation•Effect of heat treatment and cooling rate?
4 Cu (mass%)
850C
1.8
910C
Cu
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Objectives:Objectives:
In terms of the promotion of recycling steel scraps, Cu has been tried to be utilized as an effective alloying element.
Some of utilization of Cu such as solid solution strengthening and precipitation strengthening will be introduced in the presentation.
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Strengthening Mechanism
How to increase the strength of metals?
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Illustration of Strengthening Mechanism in steel
Dislocations (cars on highway) move easily within a steel
Solid solution strengthening
bumpy road
Precipitation strengthening
Dislocation strengthening
Grain refinement strengthening
traffic jam
riverbed road
dead-end road
To disturb motion of car = To increase strength = strengthening
Solute Cu
Cu nanoparticles
Ultrafine grained steel with Cu nanoparticles
Cold-rolled steel
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Effect of Cu in solid-solution
Why do we utilize Cu in solid-solution?
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Heat treatment of Cu bearing steel
Cu
Solution treatment
W.Q
Aging
or ’ (single phase)+ solute Cu
(super saturated)
Cu
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Effect of solute Cu on microstructure (ferritic steel)
Pure iron 1%Cu steel
2%Cu steel
Ferrite single phase (Cu in solid solution)Ferritic grains are refined owing to Cu addition
Steel: Fe-0~2%Cu alloy
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Effect solute Cu on microstructure and mechanical properties
Microstructure of martensite
Structures are refined as Cu content increases
Prior grain sizes tend to decrease
200m
8%Ni-1%Cu 8%Ni-3%Cu 8%Ni
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Effect solute Cu on yield strength0.
2% p
roo
f st
ress
, σ
0.2 / M
Pa
(Cu content; [Cu])1/2 / (at.%)1/2
600
750
700
650
Cu content, [Cu] / mass%
1.50 1.0 2.00.5
2.00 1.0 3.00.5
150
100
50
200
17×[at.%Cu]1/2
57×[at.%Cu]1/2
Ferritic steels
Martensitic steels
Solid solution strengthening
The addition rule is not suited to the case of the martensitic Cu steel
The influence of the solid solution strengthening by Cu clearly decreases
J. Syarif, K. Nakashima, T. Tsuchiyama and S. Takaki, ISIJ International, 2007, 2
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Difference of strengthening mechanism between the ferritic steel and the martensitic steel
Ferritic steel
b
Martensitic steel
b
Solute Cu dislocation Solute Cu dislocation
dislocation
Solid solution strengthening Dislocation strengthening
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Advantage of Cu nanoparticlesHow strong is it? Useful?
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Precipitation strengthening of Cu
E. Hornbogen and R.C. Glenn : Trans. Met. Soc. AIME, 218(1969), 1064
873K-162ks
K.NAKASHIMA et. al, ISIJ International, Vol. 42 (2002), No. 12, pp. 1541–1545
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Precipitation behavior of Cu
bcc Cu 9R 3R fcc() Cu
During aging, Cu in solid solution will transform to
P.J. Othen, M.L. Jenkins, and G.D.W. Smith: Phil. Mag., 1994, vol. 70, pp. 1–24.
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Precipitation strengthening of Cu nanoparticles
What is strengthening mechanism of Cu nanoparticles??
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Mechanism of precipitation strengthening
When a moving dislocation is pinned by dispersed precipitates as shown in Figure, shear stress ( ) required for bowing the dislocation with angle is expressed by the Eq. (1).
= (Gb/ )sin .................. (1)
Tensile stress () is given by multiplying Taylor factor to the shear stress and expressed using another constant (b) as follows:
Carbon steels with carbide: =2.8, because = /2.
=(Gb )sin ............................(2)
Mean particle spacing; was calculated with the Eq. (3).
=1.25(dp3/6fdp)1/2 - ( dp
2/4dp)...........................(3)
Where dp is diameter of the precipitates. The f is volume fraction of the precipitates
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Mechanism of precipitation strengthening
Bowing degree of Cu nanoparticles is smaller than/2
Not the Orowan mechanism, so?
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Mechanism of precipitation strengthening1. Strong obstacles
= /2
< /2
2. Weak obstacles (Cu nanoparticles)
Conversely, dislocation cuts off the particles for passing trough. Thus, </2.
Moreover, Kelly proposed
Strengthening due to differing Elastic modulus between matrix and particle
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Utilization of Cu nanoparticlesin structural steels
Are the properties changed??
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1. HSLA steels
Acceleratedcooling
Tf : 910, 850, 723C
1150C
910C-1hr
DQ RQ
W.Q.
Chemical compositions of the steel
Cu
350-690C-1hr
TMCP
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Microstructure of Cu bearing HSLA steels
RQ DQ, 910C
DQ, 850C DQ, 753C
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HSLA steelsaged at 630C
Cu nanoparticles
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HSLA steels
Recent development, Sumitomo corp has patented YP480 MPa plate steel for offshore use (fulfilled API standard) by Cu addition.
One of the largest steel companies in Japan has been developing YP550MPa.
Why?1. Cu can substitute C, thus weldability will be improved2. C u increases the strength without deteriorating ductility
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2. Utilization of Cu in a cryogenic steel
Steel: Fe-9%Ni-0.1%C-0~3Cu alloy
CuW.Q
Cu
1223K-3.6ks873K-3.6ks
Cu nanoparticles
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Utilization of Cu in a cryogenic steel
The improvement of strength–ductility balance in Cu bearing 9%Ni steels are derived from 1. Strengthening of martensitic matrix by precipitation strengthening by Cu particles 2. an increase in uniform elongation due to the rise of work-hardening rate caused by TRIP assisted effect of reversed .
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3. Utilization of Cu in Heat-Resistant SteelSteel: Fe-9%Cr-(0~4)%Cu alloy
W.Q
1223K~1423K-3.6ks
Full martensitic structure
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Utilization of Cu in Heat-Resistant Steel
CuW.Q
1223K-3.6ks873K-140MPa
Creep-properties is improved owing Creep-properties is improved owing to Cu nanoparticlesto Cu nanoparticles
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Combination of Cu nanoparticles and ultrafine grain
The ultimate method??
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Ultra-fine grained steel
Yttria powder Iron powder
Cu powder
mixing
M.M
Tubing
Hot rolling
Steel: Fe- 1.5%Cu-3vol%Y2O3
Cu
773K
Aging
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Addition Cu in Ultra-fine grained steel
Cu nanoparticles within UFF grain Effect of Cu is not significant
Why? It is thought that1. Hardness of UFG steel is too high, 2. Addition rule of the strengthening mechanism cannot be applied
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SummarySummaryIt is shown that addition of Cu can improve the mechanical properties of ferrous materials for structural use.
Both of solid solution and precipitation states, Cu can increase the hardness of the steels. Moreover, the strength-ductility balance is also improved in the low alloy and cryogenic steel.
On the other hand, the effect of Cu nanoparticles is inferior in the ultra-fine grained steel.
Recommendation Recommendation
Few works have been done to clarify the effect of Cu nanoparticles on wear behavior and fatigue properties of steels.
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Effect solute Cu on low temperature toughness
solute Cu
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Fractography of sample Charpy-tested at -50oC
Pure iron: cleavage fracture (brittle)1%Cu steel: dimple (ductile)
Pure iron1%Cu steel
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Microstructure of near fracture surface
Pure iron
Pure iron
1%Cu steel
1%Cu steel
In -50C:Pure iron: twin deformation 1%Cu steel: slip deformation due to dislocation
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DBT behavior of 8Ni-Cu steels