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A R C H I V E S
o f
F O U N D R Y E N G I N E E R I N G
Published quarterly as the organ of the Foundry Commission of the Polish Academy of Sciences
ISSN (1897-3310) Volume 10
Issue 4/2010
47 – 54
10/4
A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 47
Chromium and copper influence on the no-
dular cast iron with carbides microstructure
G. Gumienny
Department of Materials Engineering and Production Systems, Technical University of Łódź
Stefanowskiego 1/15 Street, 90-924 Łódź, Poland
Corresponding author. E-mail address: [email protected]
Received 26.07.2010; accepted in revised form 04.09.2010
Abstract
In this paper chromium to 1,00% and copper to 1,50% influence at constant molybdenum content of about 1,50% on the nodular cast iron
with carbides microstructure has been presented. It was found, that as a result of synergic addition of above-mentioned elements there is
the possibility obtaining an ausferrite in nodular cast iron with carbides castings. Conditions have been given, when in nodular cast iron
with carbides at cooling at first in the form, then air-cooling austenite transformation to upper bainite, its mixture with lower bainite,
martensite or ausferrite takes place. Transformations proceed during cooling and the crystallization of cast iron have been determined and
the casting hardness has been presented.
Keywords: Innovative foundry technologies and materials, Ductile cast iron with carbides, Bainite, Ausferrite, TDA method
1. Introduction
In nodular cast iron microstructure there is the possibility ob-
taining bainite without heat treatment [1 ÷ 4]. For that purpose to
cast iron a molybdenum and nickel in proper amount are added.
In [4] paper nickel influence at constant molybdenum content
on the nodular cast iron with carbides microstructure has been
presented. This paper is an explication and continuation of re-
searching nodular cast iron with different metal matrix micro-
structure. Chromium and copper influence on the microstructure
and hardness of nodular cast iron with carbides containing about
1,50% Mo is presented in this paper.
2. Work methodology
Tested cast iron was melted in the 20 kg, 15000 Hz frequency
induction furnace. Cast iron was superheated to 1530 C, in order
to during reaction with magnesium its temperature was amount to
about 1480 C. It guarantee total magnesium solution in liquid
metal and its maximum yield. Nodularization process was made
in the mould. The mould scheme and its dimensions are shown in
Figure 1. A master alloy in amount of 1,00% of casting mass was
inserted into the reaction chamber. This chamber was located in
the gating system behind the sprue. Behind this chamber the
mixing and the control chambers were located. Inside the control
chamber the thermocouple PtRh10-Pt (S type) was placed. It was
connected with Cristaldigraph to thermal derivative analysis
(TDA) curves recording. After the solidification finish castings
were knocking out and free air cooling.
The chemical composition was tested with using SPECTRO-
MAXx stationary metal analyzer made by Spectro Analytical
Instruments GmbH. It is presented in Table 1 together with an
equivalent carbon content Ec and a degree of eutectic saturation
Sc.
Equivalent carbon content was calculated according to:
(1)
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 48
4 3 2
29
5
400
1
10
010
0
A
A
5 6
BB
B - B
A - A
Fig. 1. The scheme of elements spacing inside the mould:
1 – experimental casting, 2 – mixing chamber, 3 – control cham-
ber, 4 – reaction chamber, 5 – sprue, 6 - thermoelement’s shield
Table 1.
The chemical composition of tested cast iron, its equivalent car-
bon content Ec and a degree of eutectic saturation Sc Chemical composition, % Ec,
% Sc
C Si Mn Mo Cr Cu Mg
2,88
4,03
2,37
2,61
0,22
0,32
1,44
1,53
0,00
1,00
0,00
1,50
0,04
0,05
3,62
4,82
0,84
1,13
The average concentration of P and S was amount to properly
0,04% and 0,01%.
Cast iron microstructure was tested on metallographic sam-
ples etched by nital, magn. ×1000 with use of Eclipse MA200
Nikon microscope. Hardness tests were made by use of HPO
hardness testing machine for 2,5/187,5/30 conditions.
3. Results
In Figure 2 (a, b) TDA curves of nodular cast iron with car-
bides containing 1,50% Mo (a) and its microstructure (b) are
presented.
a)
o
o
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d
, C
/s
900
1000
1100
1200
1300
t,
C
t = f( )
dt/d = f `( )
A B D F H K LE
Point , s t, C dt/d , C/s
A 73 1210 -0,19
B 107 1176 -1,37
D 147 1141 –
E 152 1142 0,14
F 168 1143 –
H 253 1089 -1,47
K 297 1035 -0,78
L 320 1012 -1,16
b)
microstructure: nodular graphite, upper bainite, ferrite, ledeburitic
carbides
Fig. 2 (a, b). TDA curves (a) and the microstructure (b) of nodular
cast iron with carbides containing: 2,98% C, 2,46% Si, 0,29%
Mn, 1,53% Mo, (Ec = 3,72%)
It is hypoeutectic cast iron (Ec = 3,72%) and its microstructure
consists of: nodular graphite, upper bainite, ferrite and small
amount of ledeburitic carbides.
The average hardness of castings made of that cast iron is
amount to 315HB.
10 m
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In Figure 3 (a, b) TDA curves of nodular cast iron with car-
bides containing 0,25% Cr (a) and its microstructure (b) are pre-
sented.
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s
900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
AB DE F H K L
Point , s t, C dt/d , C/s
A 112 1149 -0,04
B 129 1147 -0,33
D 154 1144 –
E 165 1144 0,15
F 181 1145 –
H 276 1102 -1,42
K 329 1042 -0,84
L 364 1008 -1,18
b)
microstructure: nodular graphite, ferrite, pearlite, upper and lower
bainite, ledeburitic carbides
Fig. 3 (a, b). TDA curves (a) and the microstructure (b) of nodular
cast iron with carbides containing: 3,48% C, 2,46% Si, 0,27%
Mn, 1,45% Mo, 0,25% Cr (Ec = 4,20%)
Cast iron microstructure consists of: nodular graphite, ferrite,
pearlite, upper and lower bainite and ledeburitic carbides. It is
hypoeutectic cast iron (Ec = 4,20%). Its solidification begins with
austenite precipitations in the melt, what causes on the derivative
curve AB thermal effect. Next the melt solidifies as an austenite +
graphite eutectic mixture (BDEFH thermal effect). Both Mo and
Cr are characterized by the straight microsegregation, so the
remaining liquid is chromium and molybdenum enriched and
crystallizes according to the metastable system and creates com-
plex ledeburitic carbides (Fe,Cr,Mo)3C at the temperature of
tH = 1102 C ÷ tL = 1008 C (Fig. 3 a). These carbides crystallize
on eutectic cells boundaries. 1,45% Mo and 0,25% Cr combina-
tion cause obtaining unfavourable metal matrix microstructure
consisting large amount of ferrite, pearlite and small amount of
upper and lower bainite. A large amount of ferrite is caused, like
in previous cast iron, by known, molybdenum ferritizing action
[5].
The average hardness of castings made of that kind of cast
iron is amount to 303HB.
Increase of Cr concentration to 0,50% caused changes of
TDA curves and the microstructure presented in Figure 4 (a, b).
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s
900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
DE F H K L
Point , s t, C dt/d , C/s
D 116 1138 –
E 132 1140 0,21
F 148 1142 –
H 290 1094 -1,21
K 342 1044 -0,57
L 381 1010 -1,27
10 m
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 50
b)
microstructure: nodular graphite, upper and lower bainite, ferrite,
pearlite, ledeburitic carbides
Fig. 4 (a, b). TDA curves (a) and the microstructure (b) of nodular
cast iron with carbides containing: 3,55% C, 2,50% Si, 0,31%
Mn, 1,53% Mo, 0,50% Cr (Ec = 4,26%)
From TDA curves results, that it is eutectic cast iron
(Ec = 4,26%), so its solidification begins with the austenite +
graphite eutectic mixture forming. Chromium concentration in-
crease to 0,50% caused decreasing eutectic transformation tem-
perature (Fig. 4 a).
From Fig. 4 b results, that Cr in amount to 0,50% caused de-
creasing of ferrite surface fraction compared to cast iron with
0,25% Cr. It testify, that chromium not only is a part of carbides,
but in a certain amount dissolves in austenite and has an influence
on its solid-state transition. Carbides surface fraction is increased.
It is presented in Figure 5 (a, b).
The average hardness of castings made of cast iron containing
1,53% Mo and 0,50% Cr was amount to 360HB and is higher than
hardness of cast iron with 0,25% Cr. It is caused by increased
carbides surface fraction, too (Fig. 5 b).
a)
microstructure: nodular graphite, ferrite, pearlite, upper and lower
bainite, ledeburitic carbides
b)
microstructure: nodular graphite, upper and lower bainite, ferrite,
pearlite, ledeburitic carbides
Fig. 5 (a, b). Nodular cast iron microstructure containing 0,25%
Cr (a) and 0,50% Cr (b)
TDA curves and the microstructure of cast iron containing
1,00% Cr are presented in Figure 6 (a, b).
10 m 100 m
100 m
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 51
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
DE F H K L
Point , s t, C dt/d , C/s
D 115 1138 –
E 132 1140 0,21
F 160 1143 –
H 277 1101 -1,31
K 317 1062 -0,62
L 344 1035 -1,37
b)
microstructure: nodular graphite, pearlite, ledeburitic carbides,
ferrite
Fig. 6 (a, b). TDA curves (a) and the microstructure (b) of nodular
cast iron with carbides containing: 3,56% C, 2,50% Si, 0,27%
Mn, 1,50% Mo, 1,00% Cr (Ec = 4,27%)
From Fig. 6 a results, that chromium content increase to
1,00% did not caused eutectic transformation temperature change.
Temperature recalescence was increased of about 1 C compared
to cast iron with 0,50% Cr and amount to 5 C. Metal matrix
microstructure of cast iron changes essentially. It consists of
pearlite, ledeburitic carbides and small amount of ferrite. Results
from it, that in cast iron with 1,00% Cr molybdenum amount
equals 1,50% did not caused austenite transformation to upper or
lower bainite during permanent cooling. Carbides amount is
similar, like in cast iron with 0,50% Cr. It is presented in Figure 7.
microstructure: nodular graphite, pearlite, ledeburitic carbides,
ferrite
Fig. 7. Nodular cast iron microstructure containing 1,00% Cr
The average hardness of pearlitic-ferritic cast iron with car-
bides is amount to 307HB.
In Figure 8 (a, b) TDA curves of nodular cast iron with car-
bides containing 1,49% Mo and 0,50% Cu (a) and its microstruc-
ture (b) are presented.
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s
900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
AB D F H K LE
Point , s t, C dt/d , C/s
A 78 1223 -1,40
B 91 1200 -2,04
D 134 1159 –
E 148 1160 0,12
F 153 1160 –
10 m
100 m
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 52
H 292 1114 -1,86
K 348 1038 -0,90
L 362 1023 -1,23
b)
microstructure: nodular graphite, upper and lower bainite, ferrite,
pearlite, ledeburitic carbides
Fig. 8 (a, b). TDA curves (a) and the microstructure (b) of nodular
cast iron with carbides containing: 4,03% C, 2,51% Si, 0,24%
Mn, 1,49% Mo, 0,50% Cu (Ec = 4,82%)
From TDA curves results, that it is hypereutectic cast iron, so
its solidification begins with the nodular graphite precipitation
(AB thermal effect). Copper addition caused increase of austenite
+ graphite eutectic mixture crystallization temperature (BDEFH
thermal effect) compared to cast iron with chromium. Molybde-
num presence causes, like in previously described cast irons,
solidification of the remaining liquid according to the metastable
system and (Fe,Mo)3C carbides forming. Compared with cast iron
containing 1,53% Mo and 0,50% Cr it has reduced amount of
carbides and similar amount of ferrite and pearlite. It is exemplary
presented in Figure 9.
microstructure: nodular graphite, upper and lower bainite, ferrite,
pearlite, ledeburitic carbides
Fig. 9. Nodular cast iron microstructure containing 0,50% Cu
The average hardness of cast iron with about 1,50% Mo and
0,50% Cu was amount to 328HB.
Increase of copper content to 1,00% caused in cast iron
changes presented in Figure 10 (a, b).
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s
900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
ABD F H K LE
Point , s t, C dt/d , C/s
A 139 1156 0,04
B 146 1156 -0,31
D 168 1153 –
E 173 1153 0,09
F 199 1153 –
H 294 1114 -1,61
K 355 1038 -0,77
L 376 1015 -1,24
b)
microstructure: nodular graphite, upper and lower bainite, marten-
site, ferrite, ledeburitic carbides, retained austenite
Fig. 10 (a, b). TDA curves (a) and the microstructure (b) of nodu-
lar cast iron with carbides containing: 3,50% C, 2,49% Si, 0,32%
Mn, 1,50% Mo, 1,00% Cu (Ec = 4,32%)
10 m
10 m
100 m
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 53
In this cast iron eutectic transformation takes place in the
temperature of 7 C less, than in cast iron with 0,50% Cu, but it is
still higher than in cast iron with chromium. Molybdenum pres-
ence caused ledeburitic carbides forming (HKL thermal effect,
Fig. 10 a). Copper increase caused small amount of martensite
forming, but did not change significantly carbides amount. It is
important, that ferrite amount is decreased and pearlite disap-
peared in cast iron metal matrix microstructure.
The average hardness of castings made of cast iron containing
about 1,50% Mo and 1,00% Cu was amount to 379HB and it is
51HB higher, than hardness of castings made of cast iron contain-
ing 0,50% Cu.
TDA curves and the microstructure of cast iron containing
1,50% Mo and 1,50% Cu is presented in Figure 11 (a, b).
a)
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d,
oC
/s
800
900
1000
1100
1200
1300
1400
t, o
C
t = f( )
dt/d = f `( )
DE F H K L
Point , s t, C dt/d , C/s
D 113 1157 –
E 123 1158 0,20
F 140 1159 –
H 274 1113 -1,52
K 334 1038 -0,69
L 351 1021 -1,23
b)
microstructure: nodular graphite, martensite, upper and lower
bainite, ledeburitic carbides, retained austenite
Fig. 11 (a, b). TDA curves (a) and the microstructure (b) of nodu-
lar cast iron with carbides containing: 3,39% C, 2,54% Si, 0,29%
Mn, 1,50% Mo, 1,50% Cu (Ec = 4,26%)
It is eutectic cast iron and its microstructure consists of: nodu-
lar graphite, martensite, upper and lower bainite, ledeburitic car-
bides and retained austenite. Eutectic transformation temperature
in this cast iron is similar to the temperature of this transformation
in cast iron with 0,50% Cu (DEFH thermal effect, Fig. 11 a) and it
is higher than in cast iron with chromium. Compared with cast
iron containing 1,00% Cu this cast iron has got increase marten-
site surface fraction and decrease – upper and lower bainite. Re-
sults from it, that in cast iron with 1,50% Mo copper causes
hardenability increase. Carbides amount is similar to previously
described cast irons with Cu.
The average hardness of castings made of cast iron containing
about 1,50% Mo and 1,50% Cu was amount to 493HB.
Metal matrix microstructure consisting an ausferritie and car-
bides was obtained in cast iron with 0,50% Cr, 1,50% Mo and
1,00% Cu (Figure 12 b).
10 m
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A R C H I V E S o f F O U N D R Y E N G I N E E R I N G V o l u m e 1 0 , I s s u e 4 / 2 0 1 0 , 4 7 - 5 4 54
a)
o
o
0 100 200 300 400 500
, s
-4
-3
-2
-1
0
1
dt/
d
, C
/s900
1000
1100
1200
1300
1400
t,
C
t = f( )
dt/d = f `( )
A B DEF H K L
Point , s t, C dt/d , C/s
A 94 1183 -0,12
B 116 1171 -0,93
D 177 1141 –
E 188 1141 0,06
F 201 1141 –
H 286 1107 -1,09
K 358 1039 -0,68
L 392 1010 -1,01
b)
microstructure: nodular graphite, ausferrite, ledeburitic carbides
Fig. 12 (a, b). TDA curves (a) and the microstructure (b) of nodu-
lar cast iron with carbides containing: 3,32% C, 2,48% Si, 0,24%
Mn, 1,50% Mo, 0,50% Cr, 1,00% Cu (Ec = 4,09%)
From Fig. 12 a results, that it is hypoeutectic cast iron
(Ec = 4,09%). Eutectic transformation temperature is similar to the
temperature of this transformation taking place in cast iron with
chromium and molybdenum and without copper. Cast iron micro-
structure consist of: nodular graphite, ausferrite and ledeburitic
carbides. Ausferrite is highly advisable phase in wear resistant
materials, because of its possibility to pressure hardening [6].
Carbides presence should cause high wear and adhesive resis-
tance.
The average hardness of casting made of ausferritic cast iron
with carbides was amount to 340HB.
4. Conclusions
Results have indicated the following:
metal matrix microstructure consisting large amount of ferrite
and pearlite and small amount of upper and lower bainite is
obtained in cast iron containing 1,45% Mo and 0,25% Cr,
increase of chromium content to 0,50% decreases ferrite
amount and increases carbides amount in cast iron with about
1,50% Mo,
1,00% chromium addition makes impossible obtain bainite as-
cast in cast iron with 1,50% Mo,
a presence of small amount of lower bainite and pearlite and
decrease of ferrite amount is caused by 0,50% Cu addition in
cast iron with molybdenum,
austenite stability is increased because of 1,50% Cu addition,
synergic addition of 1,50% Mo, 1,00% Cu and 0,50% Cr make
possible to obtain an ausferrite in metal matrix microstructure
of nodular cast iron with carbides.
Scientific project financed from means of budget on science in years 2009 ÷ 2012 as research project N508 411437.
References
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with Cr and Mo, Archives of Foundry Engineering, Vol. 7,
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[2] S. Pietrowski, G. Gumienny, Crystallization of nodular cast
iron with carbides, Archives of Foundry Engineering, Vol. 8,
Issue 4 (2008) 236-240.
[3] G. Gumienny, Bainitic nodular cast iron with carbides ob-
taining with use of Inmold method, Archives of Foundry En-
gineering, Vol. 9, Issue 3 (2009) 243-248.
[4] G. Gumienny, Bainitic-martensitic nodular cast iron with
carbides, Archives of Foundry Engineering, Vol. 10, Issue 2
(2010) 63-68.
[5] The Sorelmetal Book of Ductile Iron, Metals Minerals,
Warsaw, 2006.
[6] E. Guzik, Ausferritic cast iron and its kinds – structure and
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10 m