Technical Field
[0001] The present invention relates to a steel plate and a steel pipe for line pipe that
have excellent hydrogen-induced cracking resistance. In particular, the present invention
relates to a steel plate that has excellent hydrogen-induced cracking resistance and
is suitable for use in line pipe for transportation and tanks for storage of natural
gas and crude oil, and to a steel pipe for line pipe with excellent hydrogen-induced
cracking resistance, obtained by using the steel plate.
Background Art
[0002] With the development of degradation resources containing hydrogen sulfide, mainly,
line pipe for transportation and tanks for storage of oil, gas, etc. , require so-called
sour resistance, such as hydrogen-induced cracking resistance or stress-corrosion
cracking resistance. Hereinafter, a steel plate that exhibits the adequate sour resistance
is sometimes referred to as a "sour-resistant steel plate" in some cases. Hydrogen-induced
cracking (hereinafter sometimes referred to as "HIC") is known as a crack caused by
the penetration of hydrogen thereinto due to a corrosion reaction with the hydrogen
sulfide or the like, and the collection and gasification of the hydrogen at non-metallic
inclusions, such as MnS or Nb(C, N).
[0003] HIC is also known to have a tendency to occur in segregation zones, including a center
segregation and internal cracks of a cast strip, particularly, at an inclusion such
as MnS, as a starting point. For this reason, some techniques for enhancing HIC resistance
have been proposed. For example, Patent Document 1 discloses that a steel material
has improved HIC resistance by suppressing segregation degrees of Mn, Nb, and Ti at
the center in the thickness direction of a steel plate. Patent Document 2 discloses
a method for suppressing HIC that would occur in MnS or a Ca-based acid sulfide as
a starting point, by using a parameter formula that includes the contents of Ca, O
and S.
[0004] These methods suppress the occurrence of a large amount of HIC, but in some cases,
fine HIC can occur locally at a number of sites.
[0005] Meanwhile, a steel plate is subjected to melting, casting, and hot-rolling, and then
it undergoes an HIC test before being dispatched as a product. However, it takes several
weeks to obtain the result of the HIC test. Once the HIC occurs during the HIC test,
the above-mentioned steel plate cannot be dispatched as a product with excellent hydrogen-induced
cracking resistance. Because of this, the steel plate needs to be manufactured again,
that is, melted again to produce a product, and then the product needs to undergo
the HIC test again. This increases the manufacturing time period and might possibly
result in missing the deadline or the like.
[0006] For this reason, it is considered that if the HIC resistance can be evaluated at
the stage of a cast strip after the casting without performing the HIC test after
hot rolling, the manufacturing time period can be significantly shortened. As mentioned
above, HIC occurs at segregation zones (center segregation, internal cracks) or inclusions,
such as MnS, as a starting point. Thus, if these can be evaluated at the stage of
the cast strip, the evaluation of the HIC resistance is considered to be possible
based on the evaluation results.
[0007] For example, in a conventional method that involves performing an HIC test after
rolling, a long procedure A-1 from casting to dispatching is carried out in the following
way. In contrast, when the HIC resistance can be evaluated at the stage of the cast
strip, the steps of "Sample Preparation (for HIC test) → HIC Test" in performing the
HIC test can be omitted as illustrated in a procedure B-1, so that products can be
dispatched at an early stage.
Procedure A-1 : Casting → Rolling → Sample Preparation (for HIC test) → HIC Test →
Dispatching
Procedure B-1: Casting → Evaluation of HIC Resistance → Rolling → Dispatching
[0008] If the result of the HIC test is no good (NG), the conventional method would be to
perform the following procedure A-2, where it takes a long time to perform steps from
the casting to re-melting. In contrast, when the HIC resistance can be evaluated at
the stage of the cast strip as illustrated in the following procedure B-2, even if
the evaluation result is NG, the steps of "Rolling → Sample Preparation (for the HIC
Test) → HIC Test" in the procedure A-2 below can be omitted, which enables a quick
start of re-melting.
Procedure A-2: Casting → Rolling → Sample Preparation (for HIC test) → HIC Test →
Re-Melting
Procedure B-2: Casting → Evaluation of HIC Resistance → Re-Melting
[0009] As such a method, Patent Document 3 discloses a method in which internal cracks are
evaluated at the stage of the cast strip. In this method, the possibility of a hot
charge rolling (HCR) operation is determined based on the evaluation result of internal
cracks.
Prior Art Document
Patent Document
Disclosure of the Invention
Problems to be Solved by the Invention
[0011] HIC is more likely to occur not only at an internal crack, but also at a center segregation
zone as a starting point. However, Patent Document 3 does not describe a method for
evaluating center segregation. Therefore, the method mentioned in Patent Document
3 is considered to be incapable of evaluating the HIC resistance caused by the center
segregation at a stage of a cast strip.
[0012] The present invention has been made in view of the foregoing circumstance, and it
is an object of the present invention to achieve a steel plate and a steel pipe that
have excellent hydrogen-induced cracking resistance, and further to achieve a steel
plate and a steel pipe that enable the evaluation of the HIC resistance by an internal
quality of a cast strip without performing an HIC test.
Means for Solving the Problems
[0013] A steel plate having excellent hydrogen-induced cracking resistance according to
the present invention that can solve the above-mentioned problem includes, in percent
by mass:
0.02 to 0.15% of C;
0.02 to 0.50% of Si;
0.6 to 2.0% of Mn;
more than 0% and 0.030% or less of P;
more than 0% and 0.003% or less of S;
0.010 to 0.08% of Al;
0.0003 to 0.0060% of Ca;
0.001 to 0.01% of N;
more than 0% and 0.0045% or less of O; and
one or more elements selected from the group consisting of:
more than 0% and 0.02% or less of REM, and
more than 0% and 0.010% or less of Zr, with the balance being iron and inevitable
impurities, wherein
a ratio (Ca/S) of the Ca to the S is 2.0 or more,
the Ca, the S, and the O satisfy a formula below: (Ca -1.25S)/O ≤ 1.80, and
further, at a stage of a slab, a maximum segregated particle size and a number density
of segregated particle having a predetermined diameter or more, at a center part in
a thickness direction of the slab are set within respective ranges of the maximum
segregated particle size and the number density of the segregated particle having
the predetermined diameter or more, that avoid occurrence of hydrogen-induced cracking
in the steel plate obtained by rolling the slab.
[0014] The above-mentioned respective ranges of the maximum segregated particle size and
the number density of the segregated particle having the predetermined diameter or
more, that avoid occurrence of hydrogen-induced cracking may be those previously determined
by method including following (i) to (iii):
- (i) the maximum segregated particle size and the number density of segregated particle
having the predetermined diameter or more, at the center part in the thickness direction
of the slab are measured;
- (ii) a hydrogen-induced cracking test is performed on a steel plate obtained by rolling
a slab, which has been cast on the same casting conditions as the above-mentioned
slab; and
- (iii) the respective ranges of the maximum segregated particle size and the number
density of the segregated particle having the predetermined diameter or more, that
avoid occurrence of hydrogen-induced cracking are determined from the maximum segregated
particle size and the number density of the segregated particle having the predetermined
diameter or more, that are measured in the step (i) and a result of the hydrogen-induced
cracking test shown in the step (ii).
[0015] A slab casted on the same casting conditions as the above-mentioned slab may be the
slab in which the maximum segregated particle size and the number density of the segregated
particle having the predetermined diameter or more, are measured.
[0016] The steel plate may be in an API (The American Petroleum Institute) X65 Grade, and
the respective ranges of the maximum segregated particle size and the number density
of the segregated particle having the predetermined diameter or more, that avoid occurrence
of hydrogen-induced cracking may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0017] The steel plate may be in an API X70 Grade, and the respective ranges of the maximum
segregated particle size and the number density of the segregated particle having
the predetermined diameter or more, that avoid occurrence of hydrogen-induced cracking
may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0018] The steel plate may be in an ASME (American Society of Mechanical Engineers) SA516
Grade 60, and the respective ranges of the maximum segregated particle size and the
number density of the segregated particle having the predetermined diameter or more,
that avoid occurrence of hydrogen-induced cracking may satisfy either of formulas
below:

and

where x is the maximum segregated particle size, and y is the number density of segregated
particle having the predetermined diameter or more.
[0019] The steel plate may be in an ASME SA516 Grade 65, and the respective ranges of the
maximum segregated particle size and the number density of the segregated particle
having the predetermined diameter or more, that avoid occurrence of hydrogen-induced
cracking may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0020] The steel plate may be in an ASME SA516 Grade 70, and the respective ranges of the
maximum segregated particle size and the number density of the segregated particle
having the predetermined diameter or more, that avoid occurrence of hydrogen-induced
cracking may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0021] The steel plate may be in an ASTM (American Society for Testing and Materials) A516
Grade 60, and the respective ranges of the maximum segregated particle size and the
number density of the segregated particle having the predetermined diameter or more,
that avoid occurrence of hydrogen-induced cracking may satisfy either of formulas
below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0022] The steel plate may be in an ASTM A516 Grade 65, and the respective ranges of the
maximum segregated particle size and the number density of the segregated particle
having the predetermined diameter or more, that avoid occurrence of hydrogen-induced
cracking may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0023] The steel plate may be in an ASTM A516 Grade 70, and the respective ranges of the
maximum segregated particle size and the number density of the segregated particle
having the predetermined diameter or more, that avoid occurrence of hydrogen-induced
cracking may satisfy either of formulas below:

and

where x is the maximum segregated particle size, and y is the number density of the
segregated particle having the predetermined diameter or more.
[0024] The steel plate may further include, as another element, one or more of elements
(A) and (B) below:
- (A) in percent by mass, one or more elements selected from the group consisting of
more than 0% and 0.005% or less of B, more than 0% and 0.1% or less of V, more than
0% and 1.5% or less of Cu, more than 0% and 1.5% or less of Ni, more than 0% and 1.5%
or less of Cr, more than 0% and 1.5% or less of Mo, and more than 0% and 0.06% or
less of Nb; and
- (B) in percent by mass, one or more elements selected from the group consisting of
more than 0% and 0.03% or less of Ti, and more than 0% and 0.01% or less of Mg.
[0025] The steel plate is suitable for use in line pipe and pressure container. The present
invention also includes a steel pipe for a line pipe formed of the steel plate.
Effects of the Invention
[0026] The present invention can provide the steel plate and the steel pipe that surely
have the excellent hydrogen-induced cracking resistance. Further, the present invention
can provide the steel plate and the steel pipe in which the HIC resistance can be
evaluated by the internal quality of a cast strip without performing an HIC test.
These steel plates are suitable for use in line pipe for transportation of natural
gas and crude oil and pressure container such as tanks for storage of natural gas
and crude oil, and the like.
Brief Description of Drawings
[0027]
Fig. 1(a) is a cross-sectional view of a slab, and Fig. 1 (b) is an enlarged view
of a section r1.
Fig. 2 shows cross-sectional views of the slab and cross-sectional views of a product.
Fig. 3 shows results of examination about the relationship between the HIC resistance,
and the maximum segregated particle sizes and the number densities at a plurality
of cross sections.
Fig. 4 is a diagram for explaining an examined surface of the slab.
Fig. 5 is a diagram showing the relationship between the maximum segregated particle
sizes and number densities and the presence or absence of HIC occurrence when using
steels of API X65 Grade and the like in Examples.
Fig. 6 is a diagram showing the relationship between the maximum segregated particle
sizes and number densities and the presence or absence of HIC occurrence when using
steels of API X70 Grade and the like in Examples.
Mode for Carrying Out the Invention
[0028] The inventors have diligently studied to solve the foregoing problems. First, the
inventors have focused on the tendency for HIC to occur at a MnS inclusion as a starting
point. As a result, it is conceived that by causing a steel to contain a rare earth
element or Zr, which has a desulfurization effect, the formation of MnS can be suppressed
to improve the hydrogen-induced cracking resistance. Furthermore, an appropriate content
of such an element is found to efficiently exhibit the desulfurization effect as mentioned
later.
[0029] Next, the inventors have focused on the tendency for HIC to occur at a segregation
zone as a starting point. Consequently, attention is paid to a "segregation degree
of center segregation" among segregation zones, particularly, the "maximum segregated
particle size (maximum diameter of a segregated particle)" and the "number density
of the segregated particle having the predetermined diameter or more". It is found
that if these parameters at a stage of a slab are restricted within certain respective
ranges, a steel plate with higher hydrogen-induced cracking resistance can be obtained,
and furthermore products can be dispatched at an early stage. This matter will be
described in detail below.
[0030] The component composition of a steel will be described below.
[0031] To ensure the excellent HIC resistance, the component composition of the steel needs
to be controlled. Furthermore, also to ensure the high strength, excellent weldability,
and the like, which are other properties required as, for example, the steel for line
pipe, the component composition of the steel plate needs to be as follows. The reasons
for specifying the contents of the respective components, including the aforesaid
rare earth elements and Zr, will be described below.
Component Composition
[C: 0.02 to 0.15%]
[0032] Carbon (C) is an element essential to ensure the strength of a base metal and a weld
bead. Thus, the C content needs to be 0.02% or more. The C content is preferably 0.03%
or more, and more preferably 0.05% or more. On the other hand, an extremely high C
content degrades the heat-affected zone (HAZ) toughness and the weldability of the
steel. Any excessive C content is more likely to form NbC or island-shaped martensite,
which possibly becomes as the starting point of HIC or a fracture propagation route.
Thus, the C content needs to be 0.15% or less. The C content is preferably 0.12% or
less, and more preferably 0.10% or less.
[Si: 0.02 to 0.50%]
[0033] Silicon (Si) has a deoxidation function and is effective in improving the strength
of a base metal and a weld bead. To exhibit these effects, the Si content is set at
0.02% or more. The Si content is preferably 0.05% or more, and more preferably 0.15%
or more. However, an extremely high Si content degrades the weldability and toughness
of the steel. Any excessive Si content forms island-shaped martensite to generate
and propagate HIC. Accordingly, the Si content needs to be suppressed to 0.50% or
less. The Si content is preferably 0.45% or less, and more preferably 0.35% or less.
[Mn: 0.6 to 2.0%]
[0034] Manganese (Mn) is an element that is effective in improving the strength of a base
metal and a weld bead. In the present invention, the Mn content is set at 0.6% or
more. The Mn content is preferably 0.8% or more, and more preferably 1.0% or more.
However, an extremely high Mn content forms MnS, degrading not only the hydrogen-induced
cracking resistance, but also the HAZ toughness and weldability. Thus, the upper limit
of Mn content is set at 2.0%. The Mn content is preferably 1.8% or less, more preferably
1.5% or less, and still more preferably 1.2% or less.
[P: more than 0% and 0.030% or less]
[0035] Phosphorus (P) is an element inevitably contained in steel. When the P content exceeds
0.030%, the roughness of a base metal and a HAZ are significantly degraded, and the
hydrogen-induced cracking resistance of the steel is also degraded. Thus, in the present
invention, the P content is restricted to 0.030% or less. The P content is preferably
0.020% or less, and more preferably 0.010% or less.
[S: more than 0% and 0.003% or less]
[0036] Sulfur (S) is an element that forms a large amount of MnS to significantly degrade
the hydrogen-induced cracking resistance when contained in a large amount. Thus, in
the present invention, the upper limit of S content is 0.003%. The S content is preferably
0.002% or less, more preferably 0.0015% or less, and still more preferably 0.0010%
or less. Thus, the S content is desirably low from the viewpoint of improving the
hydrogen-induced cracking resistance.
[Al: 0.010 to 0.08%]
[0037] Aluminum (Al) is a strong deoxidizing element. When the Al content is low, the Ca
concentration in the oxide tends to increase, that is, the Ca-based inclusions are
more likely to be formed at a superficial layer of a steel plate, causing fine HIC.
Thus, in the present invention, the Al content needs to be 0.010% or more. The Al
content is preferably 0.020% or more, and more preferably 0.030% or more. On the other
hand, when the Al content is extremely high, an Al oxide is formed in a cluster shape
and becomes a starting point of hydrogen-induced cracking. Thus, the Al content needs
to be 0.08% or less. The Al content is preferably 0.06% or less, and more preferably
0.05% or less.
[Ca: 0.0003 to 0.0060%]
[0038] Calcium (Ca) serves to control the form of a sulfide and has an effect of suppressing
the formation of MnS by forming CaS. To obtain this effect, the Ca content needs to
be 0.0003% or more. The Ca content is preferably 0.0005% or more, and more preferably
0.0010% or more. On the other hand, when the Ca content exceeds 0.0060%, HIC occurs
at many sites from the Ca-based inclusions as the starting point. Thus, in the present
invention, the upper limit of Ca content is set at 0.0060%. The Ca content is preferably
0.0045% or less, more preferably 0.0035% or less, and still more preferably 0.0025%
or less.
[N: 0.001 to 0.01%]
[0039] Nitrogen (N) precipitates as TiN in a steel microstructure, preventing austenite
grains in a HAZ zone from being coarsened and further promoting ferrite transformation
to thereby improve the toughness of the HAZ zone. To obtain these effects, the N content
needs to be 0.001% or more. The N content is preferably 0.003% or more, and more preferably
0.0040% or more. An extremely high N content, however, degrades the toughness of the
HAZ by the presence of the solid-solute N. The N content needs to be 0.01% or less.
The N content is preferably 0.008% or less, and more preferably 0.0060% or less.
[O: more than 0% and 0.0045% or less]
[0040] An oxygen (O) content is desirably low from the viewpoint of improving the cleanliness
of a steel. An extremely high O content degrades the toughness of the steel, and additionally
causes HIC at an oxide as a starting point, thereby degrading the hydrogen-induced
cracking resistance. In this regard, the O content needs to be 0.0045% or less, and
is preferably 0.0030% or less, and more preferably 0.0020% or less.
[Ca/S in terms of mass ratio: 2.0 or more]
[0041] As mentioned above, S forms MnS as a sulfide-based inclusion, and HIC might occur
at the MnS as a starting point. Thus, the sulfide-based inclusion in the steel has
its form controlled as CaS by adding Ca, thereby rendering S harmless for the HIC
resistance. To sufficiently exhibit these effects, the Ca/S needs to be set at 2.0
or more. The Ca/S is preferably 2.5 or more, and more preferably 3.0 or more. Note
that the upper limit of Ca/S is approximately 17 based on the Ca content and S content
specified by the present invention.

[0042] To avoid the occurrence of HIC due to a Ca-based oxysulfide, it is effective to suppress,
especially, CaO that is the most likely to form aggregates among Ca-based inclusions.
For this reason, a Ca content (Ca - 1.25S) that is obtained by subtracting a content
in Ca present as a sulfide (CaS) in the steel from the total Ca content in the steel
must not be excessive relative to the O content. When the Ca content (Ca - 1.25S)
is excessive relative to the O content, CaO is more likely to be formed as an oxide-based
inclusion, which makes it easier for aggregates of the CaO (coarse Ca-based inclusions)
to be formed in a larger amount at a superficial layer of a steel plate. Since these
coarse Ca-based inclusions serve as the starting point of HIC, the (Ca - 1. 25S) /O
needs to be 1.80 or less in order to obtain the excellent HIC resistance. (Ca - 1.25S)/O
is preferably 1.40 or less, more preferably 1.30 or less, still more preferably 1.20
or less, and particularly preferably 1.00 or less. Like CaO, to suppress Al
2O
3 that tends to form aggregates, the lower limit of (Ca - 1.25S)/O is approximately
0.1.
[REM: more than 0% and 0.02% or less]
[0043] A rare earth metal (REM) is an element that is effective in enhancing the hydrogen-induced
cracking resistance by suppressing the formation of MnS through the desulfurization
effect as mentioned above. To exhibit such effects, the REM content is preferably
0.0002% or more. The REM content is more preferably 0.0005% or more, and still more
preferably 0.0010% or more. On the other hand, if REM is contained in a large amount,
the effect is saturated. Thus, the upper limit of the REM content needs to be 0.02%.
From the viewpoint of preventing the clogging of an immersion nozzle during casting
to enhance the productivity, the REM content is preferably 0.015% or less, more preferably
0.010% or less, and still more preferably 0.0050% or less. Note that in the present
invention, REM means lanthanoid elements (15 elements from La to Lu), scandium (Sc),
and yttrium (Y).
[Zr: more than 0% and 0.010% or less]
[0044] Zirconium (Zr) serves to form an oxide and disperse it finely in steel, while improving
the HIC resistance by the desulfurization effect, thereby contributing to improving
the HAZ toughness. To exhibit these effects, the Zr content is preferably set at 0.0003%
or more. The Zr content is more preferably 0.0005% or more, even more preferably 0.0010%
or more, and much more preferably 0.0015% or more. On the other hand, the addition
of any excessive Zr forms coarse inclusions to degrade the hydrogen-induced cracking
resistance and the toughness of a base metal. Thus, the Zr content needs to be 0.010%
or less. The Zr content is preferably 0.0070% or less, more preferably 0.0050% or
less, and even more preferably 0.0030% or less.
[0045] The components of the steel (steel plate, steel pipe) in the present invention have
been mentioned above, with the balance being iron and inevitable impurities. In addition
to the elements mentioned above, the steel further includes:
- (a) one or more elements selected from the group consisting of B, V, Cu, Ni, Cr, Mo,
and Nb in the following contents, thereby making it possible to enhance the strength
and toughness; and/or
- (b) one or more elements selected from the group consisting of Ti and Mg in the following
contents, thereby making it possible to improve the HAZ toughness and to promote the
desulfurization, thus further improving the HIC resistance. These elements will be
described in detail below.
[B: more than 0% and 0.005% or less]
[0046] Boron (B) enhances the hardenability of a steel and the strength of a base metal
and a weld bead. Furthermore, B is bonded to N to precipitate BN while the heated
HAZ zone is cooled in welding, thus promoting ferrite transformation from the inside
of an austenite grain. In this way, B improves the HAZ toughness. To obtain these
effects, the B content is preferably 0.0002% or more. The B content is more preferably
0.0005% or more, and still more preferably 0.0010% or more. However, any excessive
B content degrades the toughness of a base metal and a HAZ zone, thus leading to degradation
in the weldability. Thus, the B content is preferably 0.005% or less. The B content
is more preferably 0.004% or less, and still more preferably 0.0030% or less.
[V: more than 0% and 0.1% or less]
[0047] Vanadium (V) is an element effective in improving the strength of steel. To obtain
this effect, the V content is preferably 0.003% or more, and more preferably 0.010%
or more. On the other hand, when the V content exceeds 0.1%, the weldability and the
toughness of a base metal would be degraded. Thus, the V content is preferably 0.1%
or less, and more preferably 0.08% or less.
[Cu: more than 0% and 1.5% or less]
[0048] Copper (Cu) is an element effective in improving the hardenability of steel. To obtain
this effect, the Cu content is preferably 0.01% or more. The Cu content is more preferably
0.05% or more, and still more preferably 0.10% or more. However, when the Cu content
exceeds 1.5%, the toughness of steel is degraded. Thus, the Cu content is preferably
1.5% or less. The Cu content is more preferably 1.0% or less, and still more preferably
0.50% or less.
[Ni: more than 0% and 1.5% or less]
[0049] Nickel (Ni) is an element effective in improving the strength and toughness of a
base metal and a weld bead. To obtain these effects, the Ni content is preferably
0.01% or more. The Ni content is more preferably 0.05% or more, and still more preferably
0.10% or more. However, an extremely high Ni content leads to an excessively expensive
steel for a structure. From the economical aspect, the Ni content is preferably 1.5%
or less. The Ni content is more preferably 1.0% or less, and still more preferably
0.50% or less.
[Cr: more than 0% and 1.5% or less]
[0050] Chromium (Cr) is an element effective in improving the strength of steel. To obtain
such an effect, the Cr content is preferably 0.01% or more. The Cr content is more
preferably 0.05% or more, and still more preferably 0.10% or more. On the other hand,
when the Cr content exceeds 1.5%, the HAZ toughness of the steel is degraded. Thus,
the Cr content is preferably 1.5% or less. The Cr content is more preferably 1.0%
or less, and still more preferably 0.50% or less.
[Mo: more than 0% and 1.5% or less]
[0051] Molybdenum (Mo) is an element effective in improving the strength and toughness of
a base metal. To exhibit this effect, the Mo content is preferably 0.01% or more.
The Mo content is more preferably 0.05% or more, and still more preferably 0.10% or
more. However, when the Mo content exceeds 1.5%, the HAZ toughness and weldability
of the steel are degraded. Thus, the Mo content is preferably 1.5% or less, more preferably
1.0% or less, and still more preferably 0.50% or less.
[Nb: more than 0% and 0.06% or less]
[0052] Niobium (Nb) is an element effective in enhancing the strength of steel and the toughness
of a base metal without degrading its weldability. To obtain this effect, the Nb content
is preferably 0.002% or more. The Nb content is more preferably 0.010% or more, and
still more preferably 0.020% or more. However, when the Nb content exceeds 0.06%,
the toughness of the base metal and HAZ is degraded. Thus, in the present invention,
the upper limit of Nb content is preferably set at 0.06%. The Nb content is more preferably
0.050% or less, still more preferably 0.040% or less, and yet more preferably 0.030%
or less.
[Ti: more than 0% and 0.03% or less]
[0053] Titanium (Ti) precipitates as TiN in steel, thereby preventing austenite grains in
a HAZ zone from being coarsened during welding and thereby promoting the ferrite transformation.
Thus, Ti is an element that is effective in improving the toughness of the HAZ zone.
Furthermore, Ti exhibits the desulfurization effect, and thus is an element that is
effective in improving the HIC resistance. To obtain these effects, the Ti content
is preferably 0.003% or more, more preferably 0.005% or more, and still more preferably
0.010% or more. On the other hand, any excessive Ti content leads to an increase in
the amount of solid-solute Ti and precipitated TiC, thus degrading the toughnesses
of a base metal and a HAZ zone. Thus, the Ti content is preferably 0.03% or less,
and more preferably 0.02% or less.
[Mg: more than 0% and 0.01% or less]
[0054] Magnesium (Mg) is an element that is effective in improving the toughness of steel
through refinement of crystal grains, and also effective in improving the HIC resistance
because of its desulfurization effect. To obtain these effects, the Mg content is
preferably 0.0003% or more. The Mg content is more preferably 0.001% or more. On the
other hand, an excessive Mg content saturates its effect. Thus, the upper limit of
the Mg content is preferably 0.01%. The Mg content is more preferably 0.005% or less.
[0055] In the steel plate of the present invention, at a stage of a slab, a maximum segregated
particle size and a number density of segregated particle having a predetermined diameter
or more, at a center part in a thickness direction of the slab are set within respective
ranges of the maximum segregated particle size and the number density of the segregated
particle having the predetermined diameter or more, that avoid occurrence of hydrogen-induced
cracking in the steel plate obtained by rolling the slab. Because of this, the steel
plate of the present invention has excellent hydrogen-induced cracking resistance.
The term "above-mentioned ranges" as used herein means the previously-determined ranges
of the maximum segregated particle size and the number density of the segregated particle
having the predetermined diameter or more, that avoid the occurrence of HIC in the
steel plate obtained by rolling the slab.
[0056] In this way, the segregation degree of center segregation at a stage of the slab
is evaluated, specifically, the "maximum segregated particle size (maximum diameter
of a segregated particle)" and the "number density of the segregated particle having
the predetermined diameter or more" are set within the respective predetermined ranges.
This arrangement can produce a steel plate with high hydrogen-induced cracking resistance,
and can dispatch products at an early stage. The reason for this will be described
below. Note that in the following, the "number density of the segregated particle
having the predetermined diameter or more" will be simply referred to as the "number
density of segregated particles" or "number density" in some cases.
[0057] First, a description will be given on the segregation degree of the center segregation,
and the maximum segregated particle size and the number density, which serve as evaluation
indexes of the segregation degree.
[0058] Segregation of components is present at internal cracks or center segregation zones
of the slab. As the segregation degree of the component becomes higher, HIC is more
likely to occur, which is well known, for example, as described in
JP 2007-136496 A. Furthermore, segregation creates a hard microstructure made of MA (Martensite-Austenite
constituent, an island-shaped martensite), perlite band, or the like. As the segregation
degree becomes higher, the hard microstructure is more likely to be formed, whereby
HIC propagates and extends along the hard microstructure. In the embodiment, the HIC
resistance is evaluated, particularly, by taking into account the segregation degree
of the center segregation.
[0059] Note that segregation is also present between secondary dendritic branches. That
is, microsegregation can also occur. However, the spacing between the secondary dendritic
branches is so small that no HIC propagates and extends. Thus, this state is not problematic
in terms of the quality. Therefore, the present invention does not consider the microsegregation.
[0060] In the present invention, the segregation degree of the center segregation is evaluated
from the "maximum segregated particle size" and the "number density of the segregated
particle having the predetermined diameter or more". Various methods for examining
the segregation degree of the center segregation have been proposed. There is a correlation
between the "segregated particle size" and the "segregation degree of the center segregation".
As the "segregated particle size" is increased, the "segregation degree of the center
segregation" tends to become higher (see reference: NKK technical report No. 121 (1988)).
That is, there is a correlation between the maximum segregated particle size and the
segregation degree of the center segregation. As the "segregation degree of the center
segregation" becomes higher, HIC is more likely to occur. Thus, as the maximum segregated
particle size is increased, HIC is also more likely to occur.
[0061] The "predetermined diameter" mentioned in the above-mentioned "number density of
the segregated particle having the predetermined diameter or more" can be set at the
same diameter as a "predetermined diameter" mentioned in a "number density m1 of segregated
particle having a predetermined diameter or more", which is measured in a section
r1 of the slab shown in Fig. 2(a) to be mentioned later. For example, when the "predetermined
diameter" obtained upon measurement of the slab is, for example, 1.2 mm in diameter,
the "predetermined diameter" of a product can also be set at 1.2 mm in diameter.
[0062] There is also a correlation between the "number density of the segregated particle
having the predetermined diameter or more" and the "maximum segregated particle size".
As the number density increases, the "maximum segregated particle size" tends to be
larger (see reference:
CAMP-ISIJ Vol. 2 (1989), p. 1150). As mentioned above, as the maximum segregated particle size is increased, the "segregation
degree of the center segregation" tends to become higher. Thus, as the above-mentioned
number density is increased, the "segregation degree of the center segregation" becomes
higher, that is, HIC is more likely to occur.
[0063] As can be seen from these facts, it is first found that the HIC resistance can be
evaluated by the "maximum segregated particle size" and the "number density of the
segregated particle having the predetermined diameter or more", whereby the HIC can
be suppressed by controlling them together, i.e., the "maximum segregated particle
size" and the "number density of the segregated particle having the predetermined
diameter or more".
[0064] Then, the inventors have found that if the HIC resistance of a steel plate after
rolling can be determined in advance by using the above-mentioned maximum segregated
particle size and the number density of a steel strip at a stage of a slab, i.e.,
after casting and before rolling, the HIC test does not need to be performed on the
steel plate as a product, thereby omitting a step therefor. Consequently, products
can be dispatched at an early stage. In particular, the above-mentioned maximum segregated
particle size and the number density can be virtually measured as mentioned below,
which has advantages of being capable of easily examining the segregation degree in
a short time.
[0065] Next, a description will be given on the way to determine the segregation degree
of center segregation in a target slab, specifically, the above-mentioned maximum
segregated particle size and the number density.
[0066] First, a slab obtained by casting is cut in the thickness direction, i.e., in the
direction perpendicular to the casting direction as shown in Fig. 1, and then is examined
for the segregation degree of the center segregation.
[0067] The level of the center segregation (segregated particle size, the number of segregated
particle having the predetermined particle size or more) is varied in the slab width
direction and thus occasionally deteriorates at a specific part of the slab in the
width direction. As illustrated in Fig. 1, by setting a cross section perpendicular
to the casting direction as an object to be examined, a part where the center segregation
becomes worst can be examined.
[0068] On the slab cross section shown in Fig. 1, a region R3 in the slab, with a width
W-D, except for regions from both ends of a slab width W to D/2 of the slab thickness
D, is examined for indexes of the segregation degree of the center segregation, i.e.,
the "maximum segregated particle size" and the "number density of the segregated particle
having the predetermined diameter or more".
[0069] The reason why the above-mentioned region R3 is examined is as follows. That is,
the center segregation is a defect formed at a final solidification zone. As shown
in Fig. 1, the regions R1 and R2 are cooled from a wide-surface side and a narrow-surface
side, while the region R3 is mainly cooled only from a wide-surface side. In the region
R3, solidification proceeds from the wide surface toward the center in the thickness
direction of the slab, and thereby the center part in the thickness direction of the
slab becomes the final solidification zone. The center segregation occurs in the vicinity
of the center part in the thickness direction of the slab, which is the final solidification
zone in the region R3. For this reason, the present invention examines the segregation
degree of the center segregation in the vicinity of the center part in the thickness
direction of the region R3 as mentioned above.
[0070] Now, a description will be given on one example of a measurement method for the "maximum
segregated particle size" and the "number density of the segregated particles" with
reference to Fig. 1.
[0071] As shown in Fig. 1(a), the vicinity of the center part in the thickness direction
of the region R3 in the slab (for example, ±15 mm from the center of the thickness
D) is divided into individual n predetermined sections r1, r2, r3 ... rn (where n
is a natural number of 1 or more) in the width direction. Then, the "maximum segregated
particle size" and the "number density" in each section are measured. Here, each of
the predetermined sections r1, r2, r3 ... rn is a rectangular region with W1 in width
x D1 in thickness, as the section r1 is shown as an example in Fig. 1(b).
[0072] Regarding the above-mentioned "number density", i.e., the number density of the segregated
particle having the predetermined diameter or more, as shown in Fig. 1(b), suppose
that N segregated particles, each having the predetermined diameter or more, exist
in the section r1. In this case, the "number density of the segregated particle having
the predetermined diameter or more" in the section r1 is determined from N/(W1 x D1).
[0073] Then, a description will be given on the way to determine threshold values of the
maximum segregated particle size and of the number density, which are used for evaluation
of the HIC resistance of the slab, i.e., the respective ranges of the maximum segregated
particle size and the number density that avoid the occurrence of the HIC in the steel
plate obtained by rolling the slab.
[0074] The above-mentioned threshold values are determined previously, but their determination
method is not particularly limited to the following method. An example of the method
for determining the threshold values will include the following steps (i) to (iii).
The details of the method will be described below.
- (i) The maximum segregated particle size and the number density of the segregated
particle having the predetermined diameter or more, at a center part in a thickness
direction of the slab are measured.
- (ii) An HIC test is performed on a steel plate that is obtained by rolling a slab,
which has been cast on the same casting conditions as the above-mentioned slab.
- (iii) The respective ranges of the maximum segregated particle size and the number
density of the segregated particle having the predetermined diameter or more, that
avoid occurrence of hydrogen-induced cracking are determined from the maximum segregated
particle size and the number density of the segregated particle having the predetermined
diameter or more, that are measured in the step (i) and a result of the HIC test shown
in the step (ii).
[0075] A slab is cast on the same casting conditions as the slab in which the maximum segregated
particle size and the number density of the segregated particles are measured, and
then the slab is hot-rolled, thereby manufacturing a steel plate for measurement of
the threshold value. An HIC test is performed on the steel plate to check the presence
or absence of HIC occurrence. The HIC test is performed by a method specified by the
National Association of Corrosion and Engineer (NACE) standard TM0284-2003, as mentioned
in Examples below.
[0076] The term "same casting conditions" as used herein includes: i) a casting speed is
constant, ii) an abnormal state in operation, such as clogging of a nozzle, does not
occur, and iii) cooling conditions and a distance between rolls are the same. When
determining the threshold values, the "segregation degree obtained by examining a
slab" is related to the "HIC test result for a product". However, if the HIC resistances
of the slab and its product are different from each other, the threshold value cannot
be determined. The operation factors i) to iii) significantly affect the center segregation,
which will also affect the HIC resistance. Thus, the different operation factors lead
to different HIC resistances. For this reason, the steel plate for the HIC test is
preferably one obtained by manufacturing using a slab which has been cast on the same
casting conditions (operation factors) as the slab in which the maximum segregated
particle size and the number density are examined. In particular, the slab in which
the above-mentioned maximum segregated particle size and the number density are examined
is preferably the same as the slab for the HIC test.
[0077] In the HIC test, it is examined whether or not HIC occurs in a region of a product
(steel plate) that corresponds to the region R3 of the slab shown in Fig. 1. Specifically,
as shown in Fig. 1, the region R3 of the slab is divided into the individual n predetermined
sections r1, r2, r3 ... rn in the width direction. Then, it is examined whether or
not HIC occurs in regions of the product (steel plate) that correspond to the respective
regions r1, r2, r3 ... rn. As illustrated in Fig. 2, the regions to be evaluated for
the HIC resistance vary depending on the rolling direction during the rolling using
the slab shown in Fig. 1.
[0078] When rolling the slab in the casting direction, that is, when the rolling direction
is identical to the casting direction, as shown in Fig. 2(a), the width of the region
does not change before and after the rolling, and thus a slab width W is the same
as a product width W, i.e., slab width W = product width W. In this case, as illustrated
in Fig. 2(a), the regions corresponding to the "regions R1 and R2 of the slab" are
"regions R11 and R12 ranging from both ends of the width W of the product to D/2 of
the product width D. The region of the product corresponding to the "region R3 of
the slab" is a "region R13 with a width W-D, except for regions from both ends of
a width W of the product to D/2 of the product width D".
[0079] As shown in Fig. 2(a), regions corresponding to the "sections r1, r2, r3 ... rn in
the region R3 of the slab" correspond to "sections r11, r12, r13 ... r1n" that are
obtained by dividing the region R13 of the product into the individual n predetermined
sections in the width direction, respectively. Here, each of the predetermined sections
r11, r12, r13 ... r1n is a rectangular region with W1 in width x D1 in thickness.
[0080] On the other hand, as shown in Fig. 2(b), when rolling the slab in the width direction,
that is, when the rolling direction includes the width direction, the width of each
slab changes from W before the rolling to Wa after the rolling, and thus the slab
width W is smaller than the product width Wa, i.e., slab width W < product width Wa.
In this case, as shown in Fig. 2(b), the regions R21, R22, and R23 corresponding to
the slab regions R1, R2, and R3 are determined by a rolling reduction, i.e., product
width Wa/slab width W. Among these regions, it is confirmed whether or not HIC occurs
in the region R23.
[0081] The respective ranges of the maximum segregated particle size and the number density
that avoid the occurrence of HIC are determined from the above-mentioned "'maximum
segregated particle size' and 'number density' that are obtained by the examination
of the slab" and the above-mentioned "the HIC test result of the product".
[0082] The segregation degree of the center segregation can be evaluated by the "maximum
segregated particle size" and the "number density of the segregated particles" as
mentioned above. Thus, the boundary (threshold value) for determining whether HIC
occurs or not due to the center segregation can be represented by a function fθ(x,
y) where x is the maximum segregated particle size and y is the number density. In
the present invention, a "threshold function fθ(x, y) of the maximum segregated particle
size and the number density" is determined, and based on this threshold function,
the HIC occurrence range is determined.
[0083] When determining the threshold function fθ(x, y), the results obtained from the region
of the slab and the corresponding region of the product are correlated to each other.
For instance,
(I) in the case of rolling the slab in the casting direction as illustrated in Fig.
2(a), suppose that the product region r11 is in the state of the "presence of HIC
occurrence", the product region r12 is in the state of the "presence of HIC occurrence",
... the product region r1n is in the state of the "absence of HIC occurrence" in the
HIC test. The determination is made as follows.
(I-1) when the slab region r1 has the maximum segregated particle size x1 and the
number density m1, the determination of the "presence of HIC occurrence" is made as
the result of the product region r11;
(I-2) when the slab region r2 has the maximum segregated particle size x2 and the
number density m2, the determination of the "presence of HIC occurrence" is made as
the result of the product region r12; and
(1-3) when the slab region rn has the maximum segregated particle size xn and the
number density mn, the determination of the "absence of HIC occurrence" is made as
the result of the product region r1n.
(II) In the case of rolling the slab in the width direction as illustrated in Fig.
2(b), suppose that the product region r21 is in the state of the "presence of HIC
occurrence", the product region r22 is in the state of the "presence of HIC occurrence",
... the product region r2n is in the state of the "absence of HIC occurrence" in the
HIC test. The determination is made as follows:
(II-1) when the slab region r1 has the maximum segregated particle size x1 and the
number density m1, the determination of the "presence of HIC occurrence" is made as
the result of the product region r21;
(II-2) when the slab region r2 has the maximum segregated particle size x2 and the
number density m2, the determination of the "presence of HIC occurrence" is made as
the result of the product region r22; and
(II-3) when the slab region rn has the maximum segregated particle size xn and the
number density mn, the determination of the "absence of HIC occurrence" is made as
the result of the product region r2n.
[0084] The threshold function fθ(x, y) of the maximum segregated particle size and the number
density that serves as the boundary of the presence or absence of HIC occurrence is
determined from the above-mentioned plurality of results. Based on the threshold function
fθ(x, y), the "respective ranges of the maximum segregated particle size and the number
density that cause HIC" (HIC occurrence range) and the "respective ranges of the maximum
segregated particle size and the number density that avoid the occurrence of HIC"
(HIC non-occurrence range) are determined. If the measured values of the maximum segregated
particle size and the number density of the target slab are within the above-mentioned
HIC occurrence range, the evaluation result of the HIC resistance of the slab is rated
as "NG", that is, re-melting is determined to be necessary. If they are within the
above-mentioned HIC non-occurrence range, the evaluation result of the HIC resistance
is rated as "OK", that is, the product obtained by sequentially rolling is also determined
to have the evaluation of the HIC resistance rated as "OK". In this way, the present
invention can precisely evaluate or analyze the internal quality of a slab by using
the maximum segregated particle size and the number density for the evaluation of
the HIC resistance, and thereby can evaluate the HIC resistance at a stage of the
slab. Consequently, the HIC test that would require several weeks can be omitted,
thereby significantly shortening a time period from the manufacture to dispatching.
[0085] The steel plate in the present invention is a steel plate in which the "maximum segregated
particle size x" and the "number density y of the segregated particle having the predetermined
diameter or more" are measured at the center part in the thickness direction of the
region R3 at the slab cross section at a stage of the slab, and the measured x and
y are within the "HIC non-occurrence range" determined by the threshold value fθ(x,y).
Since this steel plate is considered to have a low segregation degree of the center
segregation zone, no HIC is determined to occur due to the center segregation.
[0086] Note that the threshold value is preferably determined by using the measurement results
of the maximum segregated particle size and the number density in a plurality of slabs
and the HIC test results. The measurement results of the maximum segregated particle
size and the number density of the plurality of slabs and the HIC test results can
be used to obtain the threshold value with higher accuracy, which can reduce the misjudgment
of the presence or absence of HIC occurrence.
[0087] The segregation zone and the HIC resistance may be evaluated by examining one cross
section of the slab or product, or alternatively by examining two or more cross sections
thereof. Fig. 3 hereinafter shows the results obtained by examining a plurality of
cross sections of the slab of the same charge. In Fig. 3, Example 1 is an example
of examining two cross sections of the slab of the same charge, and Example 2 is an
example of examining three cross sections of the slab of the same charge. In either
example, the result is obtained by examining the slab that is in conformity with API
X65 Grade.
[0088] As shown in Fig. 3, in Example 1, the respective maximum segregated particle sizes
of the two cross sections are 1.12 mm and 1.14 mm, and the number density of either
cross section is 0 particles/m
2. In the HIC test, no HIC occurs at the center segregation zone as a starting point
on either cross section. In Example 2, the respective maximum segregated particle
sizes of the three cross sections are 2.23 mm, 2.25 mm, and 2.26 mm, and the number
density in each of all cross sections is 1,667 particles/m
2. At all the cross sections, HIC occurs at the center segregation zones as the starting
points.
[0089] In this way, regarding the slab of the same charge, even different cross sections
of the slab exhibit substantially the same results. In addition, it is confirmed that
also when examining the cross section of each of 50 charges, the respective charges
show substantially the same results without misjudgment, so that the precise evaluation
can be achieved.
[0090] Although in the examples shown in Fig. 3, the slab in conformity with the API X65
Grade is used for evaluation. Alternatively, a slab in another strength grade, for
example, a slab of API X70 Grade or higher grade does not differ from the API X65
Grade slab in formation of segregation zones or in variations in the features of the
segregation zones. Thus, the number of cross sections to be examined is not limited.
[0091] The examination position (examined surface) of the slab is preferably a stationary
part as shown in Examples below, but may be a non-stationary part. The term "non-stationary
part" as used herein means a part casted when the casting condition is varied, for
example, a part casted at an initial stage of casting, such as when the casting speed
increases, or a part casted at the end of casting, such as when the casting speed
decreases. When intended to examine the non-stationary part, as shown in Fig. 4, a
part adjacent to the region subjected to the HIC test is preferably examined. Such
a part exhibits substantially the same HIC resistance as the HIC test result and can
be evaluated more precisely.
[0092] In the present invention, the above-mentioned maximum segregated particle size and
the number density are used to evaluate the HIC resistance. Because of this, the internal
quality of the cast strip can be precisely evaluated, so that based on this evaluation
result, the HIC resistance can be evaluated at a stage of the cast strip. Consequently,
the HIC test that would require several weeks can be omitted, thereby significantly
shortening a time period from the manufacture to dispatching.
[0093] The present application claims priority to Japanese Patent Application No.
2014-266490 filed on December 26, 2014, and Japanese Patent Application No.
2015-208021 filed on October 22, 2015, the disclosure of both of which is incorporated herein
by reference in its entirety.
Examples
[0094] The present invention will be more specifically described below by way of Examples,
but is not limited to the following Examples. Various modifications can be obviously
made to these Examples as long as they are adaptable to the above-mentioned and below-mentioned
concepts and are included within the scope of the present invention.
[0095] Table 1 and Figs. 5 and 6 show the experimental conditions and results for determining
the threshold value tθ. First, 7 charges were cast to obtain each of a slab corresponding
to the API X65 Grade and a slab corresponding to the API X70 Grade. One charge was
cast to obtain each of a slab corresponding to the ASME SA516 Grade 60, a slab corresponding
to the ASME SA516 Grade 65, and a slab corresponding to the ASME SA516 Grade 70. These
slabs were examined for the center segregation in the following way. Note that in
Table 1 mentioned above and Table 3 mentioned below, "X70" corresponds to API X70
Grade; "X65" to API X65 Grade; "SA516 60" to ASME SA516 Grade 60; "SA516 65" to ASME
SA516 Grade 65; and "SA516 70" to ASME SA516 Grade 70.
[0096] The conditions shown in Table 1 will be described.
<Compositions of Molten Steel in Tundish>
[0097] The concentrations of C, Mn, Nb, P, and Ca were measured by an emission spectroscopy.
The S concentration was very low and thus was difficult to measure by the emission
spectroscopy. Then, the S concentration was measured by using a combustion-infrared
absorption method.
<Casting Conditions>
Specific Water Content
[0098] 
Casting Speed
[0099] The casting speed was a drawing speed of the cast strip [m/min.], and was calculated
from the diameter (circumferential length) and the rotational speed (the number of
revolutions per unit time) of a roll (major roll) in contact with the cast strip.
(Casting)
[0100] Steels having component compositions within the range specified by the present invention
and in which their molten steels in a tundish had component compositions shown in
Table 1 were melted and subjected to continuous casting, thereby producing cast strips
or slabs, each having a thickness of 280 mm.
(Examination of Segregation Degree of Center Segregation)
[0101] Each slab was cut at a stationary part in an entire length of 10 to 15 m, and the
segregation degree of the center segregation in the stationary part was then examined
in the following way. The term "stationary part" as used herein means a part that
satisfies the following conditions. The number of cross sections for examination of
the center segregation is shown in Table 1.
- 1) Casting speed was constant.
- 2) An abnormal state in operation, such as clogging of an immersion nozzle, did not
occur.
- 3) Cooling conditions did not change.
- 4) A distance between rolls did not change.
(Examination Procedure for Center Segregation)
[0102]
(1) The cross section of the slab was polished to a level of an 800-grit level in
a range of the width W-D, except for regions from both ends of the width W to D/2
in the width direction.
(2) The polished surface was corroded with 20 g/L of picric acid, 5 g/L of cupric
chloride and 60 mL/L of a surfactant.
(3) The maximum segregated particle size was calculated in the following method.
(3-1) A part of the slab, with the width W-D, except for the regions from both ends
of the slab width W to D/2, was divided into sections, each having a size of 110 mm
in the width direction. In each section, a major axis a and a minor axis b of a segregated
particle existing in a range of ±15 mm from the center in the thickness direction,
i.e., Dn = 0.03 m, were visually measured by means of a ruler.
(3-2) A circular equivalent diameter ds of the segregated particle was calculated
by a formula below.


(3-3) The maximum particle size of the segregated particle, i.e., the "maximum segregated
diameter x" was defined as the maximum particle size dsmax of particle sizes ds in
all sections.
(4) The number density of segregated particle having the predetermined diameter or
more, was calculated in the following method.
(4-1) A part of the slab, with the width W-D, except for the regions from both ends
of the slab width W to D/2, was divided into sections, each having a size of 110 mm
in the width direction, i.e., Wn = 0.11m. In each section, the number of segregated
particles (each segregated particle having a larger size than a circle with a diameter
of 1.2 mm) existing in a range of ±15 mm from the center of the section in the thickness
direction was visually counted. Here, whether or not the segregated particle is larger
than the circle with a diameter of 1.2 mm was confirmed by overlapping a transparent
sheet having a printed circle with a diameter of 1.2 mm, on the segregated particle.
(4-2) The number density in each section was calculated by the following formula.

(Rolling)
[0103] Then, after heating each of the slabs corresponding to the API X65 Grade and API
X70 Grade to a temperature of 1,050 to 1,250°C, the hot-rolling was performed on the
slab through two or more passes. In each pass, a surface temperature of the steel
plate was set at 900°C or higher, a cumulative rolling reduction was 40% or more at
an average steel plate temperature of 1,000°C or higher, which was determined by the
calculation below, and a rolling reduction per pass was 10% or more. Subsequently,
another hot-rolling was performed such that a cumulative rolling reduction at 700°C
or higher and lower than 900°C was 20% or more, and that a rolling-end temperature
was 700°C or higher and lower than 900°C. Thereafter, water-cooling of the rolled
steel plate was started at a temperature of 650°C or higher and stopped at a temperature
of 350 to 600°C. Subsequently, the air-cooling was carried out until the room temperature,
thereby eventually producing a steel plate with a thickness of 45 mm. Meanwhile, after
hot-rolling each of the slabs corresponding to the SA516 Grade 60, SA516 Grade 65,
and SA516 Grade 70 at a rolling-end temperature of 850°C or higher, air-cooling of
the rolled steel plate was carried out until the room temperature. Subsequently, quenching
was performed on the rolled steel plate by reheating it to a temperature of 850°C
or higher and 950°C or lower, followed by a tempering process at a temperature of
600 to 700°C, thereby producing a steel plate with a thickness of 40 mm. Note that
both types of steel plates were not subjected to rolling in the slab width direction.
[0104] The average steel plate temperature was determined in the following way. Specifically,
based on data including a rolling pass schedule during rolling and a cooling method
(water-cooling or air-cooling) between the passes, the temperature at any position
of the steel plate in the thickness direction was determined by using an appropriate
calculation method, such as a finite difference method. Then, the average steel plate
temperature was defined as the average of the determined temperatures of the steel
strip in a range from the front to back surface thereof. The definition of the "average
steel plate temperature" also applied to other steel plates.
(HIC Test)
[0105] To determine a threshold value, in Examples, the HIC test was performed after the
rolling.
- (a) Samples were cut out of respective products obtained after the rolling, and the
HIC test was performed on the samples. The HIC test was performed according to the
method specified by the NACE standard TM0284-2003. (b) After the HIC test, each sample
was cut at three sites, and then respective cross sections (three cross sections)
were observed with a microscope to confirm the presence or absence of cracks (HIC).
Here, the presence or absence of cracks was confirmed in the "region R13 with the
width W-D, except for the regions from both ends of the width W of the product to
D/2" shown in Fig. 2(a).
(Determination of Threshold Function fθ(x, y) of Maximum Segregated Particle Size
and Number Density)
[0106] Figs. 5 and 6 each show the relationship between the '''maximum segregated particle
size' and 'number density' " and the "presence or absence of HIC occurrence" confirmed
by the above-mentioned HIC test. Note that Figs. 5 and 6 are diagrams plotted by taking
a plurality of data from steel plates of respective samples Nos. shown in Table 1.
Fig. 5 shows the examination results of threshold values fθ(x, y) at which HIC occurred
in components of the steels shown in Table 2 and belonging to the strength class of
API X65 Grade. Fig. 6 shows the examination results of threshold values fθ(x, y) at
which HIC occurred in components of the steels shown in Table 2 and belonging to the
strength class of API X70 Grade.
[0107] As can be seen from Fig. 5, in the slabs corresponding to the API X65 Grade, the
following results were obtained.
- (i) When the maximum segregated particle size ≤ 1.26 mm, no HIC occurred.
- (ii) When 1.26 mm < the maximum segregated particle size < 1.78 mm, different states
coexisted, specifically, HIC occurred in some sites, while no HIC occurred in other
sites. In this range, the boundary where HIC occurred or not could be represented
by a formula of y = -3,846 x x + 7,178.
For y ≤ -3,846 x x + 7,178, no HIC occurred, while
for y > -3,846 x x + 7,178, HIC occurred,
where x was the "maximum segregated particle size", and y was the "number density
of segregated particles, each of which was larger than the circle with a diameter
of 1.2 mm".
- (iii) When the maximum segregated particle size ≥ 1.78 mm, HIC occurred.
[0109]
- (i) The HIC occurrence range was represented by two ranges below.


(where y covers all values)
- (ii) The HIC non-occurrence range was represented by two ranges below.

(where y covers all values)

[0110] As can be seen from the above-mentioned description, in the slabs corresponding to
the API X65 Grade as the determination target, the following determination is made.
- (a) In the case of x ≤ 1.26 mm, it is determined that no HIC occurs, regardless of
a y value.
- (b) In the case of 1.26 mm < x < 1.78 mm, it is determined that no HIC occurs when
y ≤ -3, 846 × x + 7, 178, while HIC occurs when y > -3,846 × x + 7,178.
- (c) In the case of x ≥ 1.78 mm, it is determined that HIC occurs, regardless of a
y value.
[0111] Furthermore, Steels of ASME SA516 Grade 60, Grade 65, and ASTM A516 Grade 60 and
Grade 65 had the components corresponding to the above-mentioned API X65 Grade. Thus,
the same determination as that for the API X65 Grade applied to these other grades.
[0112] Meanwhile, referring to Fig. 6, in the slabs corresponding to the API X70 Grade,
the following results were obtained.
- (i) When the maximum segregated particle size ≤ 1.22 mm, no HIC occurred.
- (ii) When 1.22 mm < the maximum segregated particle size < 1.72 mm, different states
coexisted, specifically, HIC occurred in some sites, while no HIC occurred in other
sites. In this range, the boundary where HIC occurred or not could be represented
by a formula of y = -3,333 × x + 6,067.
For y ≤ -3,333 × x + 6,067, no HIC occurred, while
for y > -3,333 × x + 6,067, HIC occurred,
where x was the "maximum segregated particle size", and y was the "number density
of segregated particles, each of which was larger than the circle with a diameter
of 1.2 mm".
- (iii) When the maximum segregated particle size ≥ 1.72 mm, HIC occurred.
[0114]
- (i) The HIC occurrence range was represented by two ranges below.


(where y covers all values)
- (ii) The HIC non-occurrence range was represented by two ranges below.

(where y covers all values)

[0115] As can be seen from the above-mentioned description, in the slabs corresponding to
the API X70 Grade as the determination target, the following determination is made.
- (a) In the case of x ≤ 1. 22 mm, it is determined that no HIC occurs, regardless of
a y value.
- (b) In the case of 1.22 mm < x < 1.72 mm, it is determined that no HIC occurs when
y ≤ -3, 333 × x + 6, 067, while it is determined that HIC occurs when y > -3,333 ×
x + 6,067.
- (c) In the case of x ≥ 1.72 mm, it is determined that HIC occurs, regardless of a
y value.
[0116] Furthermore, Steels of ASME SA516 Grade 70 and ASTM A516 Grade 70 have the components
corresponding to the above-mentioned API X70 Grade. Thus, the same determination as
that for the API X70 Grade applied to these other grades.
(Evaluation of Slab as Determination Target)
[0117] The HIC resistance of each slab as the determination target was evaluated using the
above-mentioned threshold value. The steel with the component composition shown in
Table 2 was melted and subjected to continuous casting, thereby producing a slab as
the determination target that had the slab thickness D of 280 mm and the slab width
W of 2, 100 mm. Whether the maximum segregated particle size and the number density
of the slab as the determination target was in the HIC non-occurrence range or in
the HIC occurrence range was examined from the threshold value of the corresponding
product grade. Based on this examination result, whether or not HIC due to the center
segregation could occur in a product was determined. When the maximum segregated particle
size and the number density of the slab as the determination target were within the
threshold value range, it was determined that no HIC due to the center segregation
would occur, i.e., that the evaluation result of the HIC resistance of the slab was
rated as OK, and the obtained steel plate would have excellent HIC resistance. On
the other hand, when the maximum segregated particle size and the number density of
the slab as the determination target were outside the threshold value range, it was
determined that HIC due to the center segregation would occur, i.e., that the evaluation
result of the HIC resistance of the slab was rated as NG, and the obtained steel plate
would be inferior in the HIC resistance.
[0118] Then, after heating the above-mentioned slab to a temperature of 1, 050 to 1, 250°C,
each slab was processed by either of two patterns of hot-rolling and cooling methods,
denoted as "TMCP" or "QT" in a "hot-rolling and cooling method" column shown in Table
3. Consequently, steel plates (each having 9 to 90 mm in thickness × 2,000 to 3,500
mm in width × 12,000 to 35,000 mm in length) with various component compositions were
produced. The above-mentioned "TMCP" involved: hot-rolling through two or more passes,
in each of which a surface temperature of the steel plate was set at 900°C or higher,
a cumulative rolling reduction was 40% or more at an average steel plate temperature
of 1,000°C or higher, determined by the calculation, and a rolling reduction per pass
was 10% or more. The "TMCP" also involved: another hot-rolling such that a cumulative
rolling reduction was 20% or more at a temperature of 700°C or higher and lower than
900°C such that that the surface temperature at the end of the rolling was 850°C.
The "TMCP" further involved: starting to cool the rolled steel plate from a cooling
start surface temperature of 750°C or higher at an average cooling rate of 10°C/s
and then stopping the cooling at a temperature of 350 to 600°C, followed by air-cooling
to the room temperature. The above-mentioned "QT" was a method that involved: hot-rolling
such that the surface temperature at the end of the rolling was 850°C or higher, followed
by air-cooling to the room temperature; quenching by reheating the rolled steel plate
to a temperature of 850°C or higher and 950°C or lower; and tempering the steel plate
at 600 to 700°C.
(HIC Test)
[0119] The HIC test was performed using the above-mentioned steel plates. This HIC test
was performed according to the method specified by the NACE standard TM0284-2003.
After the HIC test, each sample was cut at three sites, and then respective cross
sections (three cross sections) were observed with a microscope to confirm the presence
or absence of cracks (HIC). The results are shown in Fig. 3.
[Table 1]
Sample No. |
Component of molten steel in tundish |
Casting conditions |
Product grade |
Number of cross sections for examination of center segregation |
C (% by mass) |
Mn (% by mass) |
Nb (% by mass) |
S (ppm by mass) |
P (ppm by mass) |
Ca (ppm by mass) |
Specific water content [L/kg-steel] |
Casting speed Vc [m/min] |
1 |
0.06 |
1.32 |
0.036 |
6 |
58 |
33 |
0.4 |
1.0 |
X70 |
1 |
2 |
0.05 |
1.28 |
0.037 |
6 |
60 |
27 |
0.4 |
1.1 |
3 |
3 |
0.05 |
1.30 |
0.037 |
6 |
41 |
30 |
0.4 |
1.3 |
1 |
4 |
0.06 |
1.27 |
0.037 |
3 |
57 |
30 |
1.2 |
1.3 |
2 |
5 |
0.05 |
1.31 |
0.037 |
7 |
42 |
34 |
1.4 |
1.3 |
1 |
6 |
0.06 |
1.34 |
0.038 |
3 |
59 |
28 |
1.4 |
1.0 |
1 |
7 |
0.05 |
1.27 |
0.036 |
6 |
66 |
32 |
1.4 |
1.1 |
1 |
8 |
0.06 |
1.28 |
0.033 |
5 |
52 |
29 |
0.4 |
1.0 |
X65 |
1 |
9 |
0.06 |
1.25 |
0.033 |
4 |
61 |
26 |
0.4 |
1.1 |
1 |
10 |
0.06 |
1.27 |
0.034 |
7 |
45 |
31 |
0.4 |
1.3 |
1 |
11 |
0.05 |
1.26 |
0.031 |
4 |
42 |
25 |
1.2 |
1.3 |
1 |
12 |
0.05 |
1.20 |
0.034 |
6 |
58 |
34 |
1.4 |
1.3 |
1 |
13 |
0.06 |
1.23 |
0.033 |
5 |
43 |
29 |
1.4 |
1.0 |
1 |
14 |
0.06 |
1.28 |
0.034 |
3 |
64 |
33 |
1.4 |
1.1 |
1 |
15 |
0.06 |
1.16 |
0.000 |
5 |
60 |
15 |
1.4 |
1.1 |
SA516 60 |
1 |
16 |
0.06 |
1.13 |
0.010 |
3 |
60 |
14 |
1.4 |
1.1 |
SA516 65 |
1 |
17 |
0.06 |
1.43 |
0.010 |
4 |
60 |
12 |
1.4 |
1.1 |
SA516 70 |
1 |
[Table 3]
Steel type No. |
Hot-rolling and cooling method |
Ca/S |
(Ca-1.25S)/O |
Maximum segregated particle size (mm) |
Number density (particles/m2) |
Evaluation of HIC resistance of slab |
Presence or absence of cracking in HIC resistance test |
Strength class |
1 |
TMCP |
7.5 |
0.96 |
0.448 |
0 |
OK |
Absence |
X65 |
2 |
TMCP |
4.4 |
0.88 |
0.439 |
0 |
OK |
Absence |
X65 |
3 |
TMCP |
7.5 |
0.96 |
0.917 |
0 |
OK |
Absence |
X65 |
4 |
TMCP |
4.4 |
0.88 |
0.930 |
0 |
OK |
Absence |
X70 |
5 |
TMCP |
5.7 |
1.02 |
0.962 |
0 |
OK |
Absence |
X65 |
6 |
TMCP |
2.7 |
0.80 |
1.210 |
0 |
OK |
Absence |
X65 |
7 |
TMCP |
3.9 |
0.73 |
0.788 |
0 |
OK |
Absence |
X70 |
8 |
TMCP |
1.9 |
0.26 |
0.552 |
0 |
OK |
Presence |
X65 |
9 |
TMCP |
5.4 |
1.89 |
0.623 |
0 |
OK |
Presence |
X65 |
10 |
TMCP |
5.8 |
1.63 |
1.684 |
333 |
OK |
Absence |
X65 |
11 |
TMCP |
6.5 |
1.11 |
1.216 |
4000 |
OK |
Absence |
X65 |
12 |
TMCP |
4.4 |
0.86 |
1.102 |
0 |
OK |
Absence |
X65 |
13 |
TMCP |
6.3 |
1.05 |
2.096 |
333 |
NG |
Presence |
X65 |
14 |
TMCP |
5.7 |
1.20 |
1.661 |
1667 |
NG |
Presence |
X65 |
15 |
TMCP |
5.5 |
1.50 |
1.245 |
333 |
OK |
Absence |
X70 |
16 |
TMCP |
4.5 |
1.22 |
1.206 |
5000 |
OK |
Absence |
X70 |
17 |
TMCP |
5.0 |
0.98 |
1.138 |
0 |
OK |
Absence |
X70 |
18 |
TMCP |
10.0 |
0.97 |
1.737 |
2333 |
NG |
Presence |
X70 |
19 |
TMCP |
4.9 |
1.20 |
1.323 |
2000 |
NG |
Presence |
X70 |
20 |
QT |
4.7 |
0.64 |
0.980 |
0 |
OK |
Absence |
SA516 60 |
21 |
QT |
6.0 |
0.84 |
1.190 |
0 |
OK |
Absence |
SA516 70 |
22 |
QT |
4.7 |
0.64 |
1.150 |
0 |
OK |
Absence |
SA516 65 |
23 |
QT |
1.7 |
0.25 |
0.686 |
0 |
OK |
Presence |
SA516 60 |
24 |
QT |
9.3 |
2.13 |
0.833 |
0 |
OK |
Presence |
SA516 70 |
[0120] Tables 2 and 3 show the following. Steel types Nos. 1 to 7, 10 to 12, 15 to 17, and
20 to 22 satisfied the specified component compositions and restricted the maximum
segregated particle size and the number density of each slab within the HIC non-occurrence
range, thereby producing the steel plates with excellent HIC resistance in the present
invention.
[0121] In contrast, in steel types Nos. 13, 14, 18, and 19, the maximum segregated particle
size and the number density of each slab deviated from the threshold value range,
that is, was within the HIC occurrence range, so that the evaluation result of the
HIC resistance of the slab was rated as NG. In the HIC test after the rolling, some
cracks were caused in the steel plates. Thus, these steels were confirmed to be inferior
in the HIC resistance. Each of the steel types Nos. 8, 9, 23, and 24 was an example
in which the maximum segregated particle size and the number density of the slab was
within the HIC non-occurrence range, but the chemical component composition of the
steel plate deviated from the composition range specified by the present invention.
Specifically, in the steel plate of the steel type No. 8, the contents of REM and
Zr were 0%, and the value (Ca/S) deviated from the specified range. In the steel plate
of the steel type No. 9, the contents of REM and Zr were 0%, and the value (Ca - 1.25S)/O
deviated from the specified range. Both steel plates Nos. 8 and 9 were inferior in
the HIC resistance. Furthermore, in the steel type No. 23, the value (Ca/S) deviated
from the specified range, while in the steel type No. 24, the value (Ca - 1.25)/O
deviated from the specified range. Both steel plates Nos. 23 and 24 were inferior
in the HIC resistance.
[0122] In the examples in which the evaluation of the HIC resistance of the slab was rated
as OK, a time period required from starting of casting to completion of a production
of the steel plate, that is, a time period until dispatching the steel plate with
the sour resistance (casting → rolling → dispatching) was 19 days. In contrast, in
cases where the steel plate obtained after the rolling was subjected to the HIC test
and then evaluated for the HIC resistance, a time period required from starting of
casting to dispatching (casting → rolling → HIC test → dispatching) was 28 days, which
was a long duration. In Examples, the HIC test after the rolling was able to be omitted,
which could significantly shorten the time period from starting of the casting to
dispatching, e.g., from 28 days to 19 days.
[0123] In the examples in which the evaluation of the HIC resistance of the slab was rated
as NG, re-melting was started at the stage of the slab. Thus, a time period required
from starting of casting to completion of a production of the steel plate, that is,
a time period until dispatching the steel plate with the sour resistance (casting
→ re-melting → rolling → dispatching) was 54 days. In contrast, in cases where the
steel plate obtained after the rolling was subjected to the HIC test and then evaluated
for the HIC resistance as the product, when the evaluation result was NG, re-melting
was started after the HIC test. Eventually, a time period required from starting of
casting to dispatching of the steel plate as the product (casting → rolling → HIC
test → re-melting → rolling → HIC test → dispatching) was 72 days, which was a longer
duration. In Examples, since the HIC test after the rolling was able to be omitted,
even though the re-melting was necessary, the time period from starting of the casting
to dispatching could be drastically shortened, e.g., from 72 days to 54 days.
[0124] As mentioned above, according to the present invention, the HIC resistance can be
evaluated at the stage of the slab as the cast strip without performing the HIC test
after the rolling, thereby making it possible to significantly shorten the manufacturing
lead time. Note that in Examples, the same HIC test is used for both the determination
of the threshold value for evaluating the HIC resistance of a slab and the confirmation
of HIC. Thus, the determination method of the present invention has high accuracy.