TECHNICAL FIELD
[0001] The present invention relates to impact-vibration equipment which impacts the narrow
side of a casting slab during continuous casting, so as to prevent the occurrence
of center segregation.
BACKGROUND ART
[0002] Macro-segregation in the form of center segregation or V-shape segregation readily
occurs in the central region and the vicinity thereof in the direction of thickness
in a continually cast slab. Macro-segregation is also referred to below as an internal
defect. Center segregation is an internal defect which occurs when solute elements
such as C, S, P, Mn, and the like (referred to below as segregation elements), which
readily segregate, increase in concentration in the crater end of a casting slab.
V-shape segregation is an internal defect which occurs when these segregation elements
increase in concentration in a V-shape on the longitudinal section of a casting slab
in the vicinity of the crater end of a casting slab.
[0003] When slabs in which such macro-segregation occurs are hot-processed to form products,
decreased toughness and hydrogen-induced cracking tend to occur. Moreover, when these
products are subjected to cold working to form final products, cracking readily occurs.
[0004] The mechanism of segregation formation in casting slabs is thought to operate in
the following manner. As solidification progresses, segregation elements form between
dendrite arms of columnar crystals which make up the solidification structure. Molten
steel containing these enriched segregation elements flows out from between the dendrite
arms of the columnar crystals as a result of solidification shrinkage of the slab
or as a result of expansion of the casting slab. This is known as bulging. The enriched
molten steel flows out and moves toward the point of complete solidification of the
crater end of the slab, and solidifies to form an enriched zone of segregation elements.
Enriched zones of segregation elements formed in this manner result in segregation.
[0005] Such segregation in casting slabs is effectively prevented by inhibiting the migration
of molten steel with enriched segregation elements remaining between the dendrite
arms of the columnar crystals, and by preventing the enriched molten steel from accumulating
locally.
[0006] Accordingly, in Patent Reference 1 there is disclosed a method of arranging an air
hammer between rolls disposed at the wide end of the slab during continuous casting,
so as to impart an impact vibration of 10-100 times/min at an amplitude of about 2.0
mm or less to the slab as it moves between the rolls.
[0007] Patent Reference 1: Japanese Patent Application Kokai Publication No.
S51-128631
[0008] In Patent Reference 2, the present applicant disclosed a casting method wherein vibrations
are applied to a slab at a position having a rectangular cross section and containing
a liquid core while the slab is being reduced by a plurality of paired guide rolls
used for reduction. This method provided for continuous impact on at least one site
on the surface of the casting slab within the reduction region.
[0009] Patent Reference 2: Japanese Patent Application Kokai Publication No.
2003-334641
[0010] The method recited in Patent Reference 2 causes bulging of the slab at a position
containing a liquid core and reduces this bulging slab with at least one pair of reduction
rolls until solidification is completed in the central region in the direction of
thickness. Patent Reference 2 further discloses a method of casting such that when
the foregoing occurs, impact is applied to the slab. According to this method, at
least one site on the slab surface is continuously impacted within a region in the
direction of casting or within the reduction region in the direction of casting, after
bulging starts and before reduction starts.
[0011] JP 2002-273554 discloses that when the cast slab having a rectangular cross sectional shape is cast,
the casting is performed while giving vibration to the cast slab by continuously hitting
the short side surface of the cast slab containing unsolidified part with a hit-vibrating
device.
[0012] JP 2006-110620 discloses in a method for continuously casting steel, when casting a cast slab having
a rectangular cross-sectional shape, the cast slab is cast while giving vibration
to the cast slab by applying continuous blows against at least one part of the short-side
surfaces of the cast slab including an unsolidified portion.
DISCLOSURE OF THE INVENTION
PROBLEM TO BE SOLVED BY THE INVENTION
[0013] However, in the method disclosed in Patent Reference 1, the following serious problems
occur when attempting to achieve a significant decrease in center segregation.
[0014] Bulging of the slab readily occurs between rolls arranged on the wide side of the
slab. When impact vibration is applied to the wide side of the bulging slab, a large
amplitude vibration cannot be applied to the central region in the direction of slab
thickness. In addition, the air hammer must be disposed between the rolls, which causes
undesirable interference with the spraying position for secondary cooling of the slab
between the rolls. Consequently, continuous impact cannot be applied when one aims
to perform optimal secondary cooling. It is also difficult for sufficient impact energy
to be propagated through the slab at an impact vibration of 10-100 times/min.
[0015] The method of Patent Reference 2 effectively prevents segregation in a slab. However,
as a result of subsequent research, the inventors have determined that there are cases
in which segregation is not sufficiently decreased, depending on the shape of the
slab.
[0016] The reason for this is that, when impact on a slab is carried out from the narrow
side of the slab, if the slab width is large, then the impact vibrations do not sufficiently
propagate to the interior of the slab in the vicinity of the central region in the
direction of width. In such cases, the columnar crystals are not broken up during
their growth, which allows the columnar crystals to grow and makes it impossible to
form a fine crystal structure. Moreover, impact is not sufficiently propagated to
the equiaxed crystals formed in the vicinity of the crater end of the slab in the
center region in the direction of width, thus bridging of the equiaxed crystals readily
occurs.
[0017] Incidentally, under the test conditions given in paragraphs 0039-0041 of Patent Reference
2 [impact amplitude of ± 3.0 mm; impact frequency of 120 times/min (2 Hz); and block
dimensions of 200 mm x 100 mm x 400 mm (62.4 kg when converted to weight)], the impact
energy is 7.8 J when the impact speed is 0.5 m/sec.
[0018] The problem to be solved by the present invention is that in the case of the prior
art, when impact is imparted from the narrow side of the slab during continuous casting,
there are cases in which it is impossible to effectively prevent the occurrence of
segregation, such as center segregation and V-shape segregation when the slab width
becomes large.
MEANS FOR SOLVING THIS PROBLEM
[0019] The present invention provides a continuous casting machine for continuous casting
of a metal in which equipment is installed for continuous soft reduction by pinch
rolls during continuous casting of a slab having a rectangular transverse cross section
when the solid fraction at a center in the direction of thickness f
s is at least in a range of 0.1-0.9, and the reduction ratio in the direction of the
slab thickness is within 1% per meter of length in the direction of casting, the equipment
being for continuously impacting both of the opposing sides of a narrow side of the
slab in a direction of slab width in at least one site where a solid fraction at the
center of the slab in the direction of thickness f
s is within a range of 0.1-0.9 at a vibration frequency of impact of 4-12 Hz, and an
impact energy of 30-150 J, the equipment comprising:
a block for impacting a narrow side of the slab;
an impact device for transmitting generated periodic impact to the block; and
a position control device for setting the distance between the block and the narrow
side of the slab,
the position control device having a structure enabling setting of a gap between a
front end of the block and the narrow side of the slab at a pull-back position of
the block based on a result of detection of a pushing position of the block on the
narrow side of the slab, or a structure for setting a gap between the slab and the
front end of the block by pushing a guide against the slab, characterized in that
the block has a structure that enables it to uniformly impact at least the narrow
side of the slab as a single unit using an impact plate disposed between two sets
of paired pinch rolls disposed adjacent to each other in a soft reduction zone formed
by a set of paired pinch rolls in a plurality of sets of paired pinch rolls.
[0020] The solid fraction at the center of the slab in the direction of thickness fs can
be obtained from the liquidus temperature T
L, the solidus temperature Ts, and the temperature at slab thickness center T, using
the formula fs = (T
L - T) / (T
L - T
s). When the temperature at the slab thickness center T is greater than or equal to
the liquidus temperature T
L of the molten steel, then f
s = 0, and when the temperature at the slab thickness center T is lower than the solidus
temperature T
s of the molten steel, then f
s = 1.0. The temperature at slab thickness center T can be obtained by a simple non-steady
state heat transfer calculation in the direction of slab thickness. This calculation
takes into consideration the casting speed, slab surface cooling, and the physical
properties of the type of steel used in casting.
ADVANTAGEOUS EFFECTS OF THE INVENTION
[0021] According to the present invention, the occurrence of segregation, such as center
segregation and V-shape segregation, is effectively prevented even when casting a
slab with a large slab width, thereby resulting in a cast slab with good internal
quality.
BRIEF DESCRIPTION OF THE DRAWINGS
[0022]
FIG. 1 is a schematic representation of an example of paired pinch rolls with impact
devices attached as viewed from the direction of the narrow side of the slab.
FIG. 2 illustrates the relative positions of a block of an impact device and a slab,
where FIG. 2 (a) illustrates a standby position of the impact device, FIG. 2 (b) illustrates
a state where the block is pushed against the narrow side of a slab, and FIG. 2 (c)
illustrates a state where the block has returned by a predetermined amount using the
position of (b) as a starting point.
FIG. 3 illustrates the relative positions of a block of another impact device and
a slab, where FIG. 3 (a) illustrates a standby position of the impact device, FIG.
3 (b) illustrates a state where a pushing guide is caused to make contact with the
narrow side of a slab, and FIG. 3 (c) illustrates a state while impact force is being
applied.
FIG. 4 is a graph illustrating the relationship between the length of the slab in
the direction of casting and the liquid core thickness in a region where the solid
fraction at the center of the slab in the direction of thickness is 0.1-0.9 for high
carbon steel.
FIG. 5 is a graph illustrating the relationship between the length in the direction
of casting and the liquid core thickness in a region where the solid fraction at the
center of the slab in the direction of thickness is 0.1-0.9 for medium carbon steel.
FIG. 6 is a chart showing experimental results.
BRIEF DESCRIPTION OF THE REFERENCE NUMERALS
[0023]
- 1
- Casting slab
- 2a, 2b
- Pinch rolls
- 3
- Block
- 3a
- Impact plate
- 6
- Impact device
- 7
- Position control device
- 8
- Pushing guide
PREFERRED EMBODIMENTS
[0024] When impacting a slab from the narrow side of the slab during continuous casting,
if the slab has a large width, there are- cases in which the occurrence of segregation
such as center segregation and V-shape segregation cannot be effectively prevented.
The present invention overcomes this problem by means of a block structure which is
enabled to uniformly impact, in a continuous manner, at least the narrow side of the
slab as a single unit between two sets of paired pinch rolls adjacent to each other.
EXAMPLES
[0025] Preferred embodiments for implementing the present invention are described in detail
below, along with the process leading to the formation of the invention.
[0026] As mentioned above, when impact on a slab is carried out from the narrow side of
the slab, if the slab width is large, then the impact vibrations do not sufficiently
propagate to the interior of the slab in the vicinity of the central region, as viewed
in the widthwise direction. In such cases, the columnar crystals are not broken up
during their growth. This allows the columnar crystals grow, and makes it impossible
to form a fine crystal structure and prevents a sufficient segregation decreasing
effect from being achieved. Moreover, the impact does not sufficiently reach the equiaxed
crystals formed in the vicinity of the crater end of the slab in the center region
in the widthwise direction. Thus, bridging of the equiaxed crystals readily occurs
and a sufficient segregation decreasing effect is not achieved.
[0027] Accordingly, the inventors conducted repeated experiments in applying impact from
both of the opposing sides of the narrow side of the slab containing a liquid core,
so as to prevent the occurrence of center segregation or V-shape segregation. Using
these experiments, the inventors investigated how to apply impact from the narrow
side of the slab so that impact vibrations would sufficiently propagate to the interior
of the slab in the vicinity of the central region in the direction of slab width.
[0028] As a result, the inventors have discovered that there exist impact frequencies and
impact energies that produce an impact-vibration effect when the solid fraction at
the center of the slab in the direction of thickness f
s in a range of 0.1-0.9. Additionally, the inventors have discovered that applying
impact within almost this entire range is very effective in decreasing segregation.
[0029] The inventors have also disclosed a method for continuous casting of steel in which
soft reduction is carried out when casting slabs having a rectangular transverse cross
section, with the solid fraction at the center of the slab in the direction of thickness
f
s within a range of 0.1-0.9 (Japanese Patent Application No.
2006-53057). When performing soft reduction, this method applies a continuous impact in the
direction of slab width at least at one site where the solid fraction f
s is within this range.
[0030] When this method is implemented, soft reduction is continuously carried out with
a reduction ratio in the direction of slab thickness of less than 1% per meter in
the direction of casting length. Moreover, both of the opposing sides of the narrow
side of the slab are continuously impacted in the direction of slab width at a vibration
frequency of impact of 4-12 Hz and at an impact energy of 30-150 J.
[0031] In Japanese Patent Application No.
2006-53057 equipment for implementing the foregoing method is disclosed. This equipment is impact-vibration
equipment having a structure that enables it to uniformly impact as a single unit
the entire surface of the narrow side of the slab at both of the opposing sides of
the narrow side of the slab, respectively, in at least one segment among segments
formed by a plurality of guide rolls.
[0032] Depending on the features of the continuous casting machine, there are cases when
soft reduction in the continuous casting of steel is not performed in segments formed
by a plurality of guide rolls, but rather, by a pinch roll assembly.
[0033] When the inventors conducted impact tests on a pinch roll assembly in the method
of continuous casting of steel disclosed in Japanese Patent Application No.
2006-53057, they were able to obtain satisfactory effects similar to when impact was applied
to the segments described above.
[0034] When impact is applied to such a pinch roll assembly, the structure is simpler than
when impact is applied to segments, as shown in Table 1 below. This structure also
provides advantages in that-it is easy to secure set-up space and it is easy to maintain
the equipment.
TABLE 1
| |
Pinch Roll Reduction |
Segment Reduction |
| Mechanism |
Single roll reduction |
Multiple roll uniform reduction |
| Structure |
No need to consider rigidity of reduction frame (simple) |
Must consider rigidity of reduction frame (complex) |
| Control |
Control includes bending and straightening counter-forces |
Control of reduction counter-forces |
| Impact imparting position |
Latter half of machine length |
Middle to latter half of machine length |
| Set-up space |
Easy to secure space (easy to maintain) |
Difficult to secure space (difficult to maintain) |
[0035] The impact-vibration equipment for continuous casting of the present invention is
based on the above findings. This equipment continuously performs soft reduction during
continuous casting of a slab having a rectangular transverse cross section, so that
the solid fraction at the center of the slab in the direction of thickness f
s is at least 0.1-0.9 and the reduction ratio in the direction of slab thickness is
within 1% per meter of length in the direction of casting. The equipment continuously
impacts both of the opposing sides of the narrow side of the slab in the direction
of slab width in at least one site where the solid fraction at the center of the slab
in the direction of thickness f
s is within a range of 0.1-0.9 at a vibration frequency of impact of 4-12 Hz and an
impact energy of 30-150 J.
[0036] This equipment comprises:
a block which impacts a narrow side of a casting slab;
an impact device which generates periodic impact and transmits the impact to the block;
and
a position control device for setting the distance between the block and the narrow
side of the slab,
wherein the block has a structure which enables it to uniformly impact, as a single
unit, the narrow side of the slab positioned between at least two sets of paired pinch
rolls disposed adjacent to each other in a soft reduction zone formed by paired pinch
rolls in a plurality of sets of pinch rolls, and
wherein the position control device sets a gap between a front end of the block and
the narrow width of the slab at a pull-back position of the block, after detecting
the pushing position of the block on the narrow side of the slab, or it performs position
control while a guide is pushed which sets the gap between the slab and the front
end of the block.
[0037] The impact-vibration equipment for continuous casting of a slab of the present invention
includes a casting slab 1, which is solidified and cast in a mold and is disposed
on the downstream side in the direction of casting, and a block 3 is disposed between
a plurality of sets of paired pinch rolls 2a, 2b, as shown in FIG. 1.
[0038] In FIG. 1, Reference Numeral 3 represents a block which impacts the narrow side of
the casting slab 1. This block 3 has a structure possessing an impact plate 3a disposed
between at least two adjacent sets of paired pinch rolls 2a, 2b in the plurality of
sets of paired pinch rolls 2a, 2b. This structure makes it possible to uniformly and
continuously impact at least the narrow side of the slab 1 as a single unit at a position
between two sets of paired pinch rolls 2a, 2b disposed adjacent to each other. From
the standpoint of durability and heat resistance, it is desirable that this block
3 be cast.
[0039] Bridging of equiaxed crystals or the like occurs at positions where the solid fraction
at the center in the direction of thickness of casting slab 1 is 0.1 or higher. However,
bridging can re-occur if the impact does not completely stop the bridging. Therefore,
it is desirable to thoroughly implement continuous impact in a range where the solid
fraction at the center in the direction of thickness of casting slab 1 is 0.4 or higher,
and it is desirable to impact the entire length between the plurality of sets of paired
pinch rolls 2a, 2b.
[0040] Moreover, the solid fraction ranging between 0.1 and 0.9 at the center in the direction
of thickness of the casting slab is within a relatively broad range, and the position
described above constantly changes during the actual casting operation, as described
below. Therefore, there are cases where the impact between two adjacent sets of paired
pinch rolls 2a, 2b is sufficient. There are also cases where impact is needed between
three adjacent sets of paired pinch rolls 2a, 2b, as shown in FIG. 1. However, installation
costs would be excessive if the equipment was required to operate over the entire
range of the solid fraction at the center in the direction of thickness of casting
slab and to impact over a lengthy area. Accordingly, impact is implemented between
three adjacent sets of paired pinch rolls 2a, 2b, for example, which is considered
to be a range that will achieve the impact-vibration effect.
[0041] In other words, it is crucial to impart vibration over a broad range of locations
in the direction of casting of the casting slab 1, and, if possible, it is desirable
that the length of the block 3 in the direction of casting be a length that enables
impact over the entire region of the plurality of sets of paired pinch rolls 2a, 2b.
However, in practice, the paired pinch rolls 2a, 2b are installed in and removed from
the continuous casting machine, thus they should be as long as possible to enable
impact without interfering with the various elements of the continuous casting machine.
[0042] The paired pinch rolls 2a, 2b have a structure that makes it possible to adjust the
amount of reduction and also to eliminate soft reduction through the use of a hydraulic
cylinder 5, which is typically attached to an upper frame 4.
[0043] Reference Numeral 6 represents an impact device to which the block 3 is attached
at the front end. The impact device 6 generates periodic impact and transmits this
impact to the block 3. An air cylinder, for example, may be used for this purpose.
This impact device 6 is disposed, for example, in two places on both of the opposing
sides of the narrow side of the slab 1 that contains a liquid core.
[0044] Reference Numeral 7 represents a position control device, which pushes the block
3 from the standby position shown in FIG. 2 (a), to the narrow side of the slab 1
[
see FIG. 2 (b)]. After detecting the pushing position, the position control device sets
the gap L (impact amplitude: about 8 mm) between the front end surface of the block
3 and the narrow side of the slab 1, at the pull-back position of the block 3 [
see FIG. 2 (c)].
[0045] The position control device 7 is not limited to the structure shown in FIG. 2, and
may also have the structure shown in FIG. 3. The position control device 7 of FIG.
3 sets the gap L (impact amplitude: about 8 mm) between the front end surface of the
block 3 and the narrow side of the slab 1 by causing a pushing guide 8 to move from
the standby position shown in FIG. 3 (a) to a position where it makes contact with
the narrow side of the slab 1 [
see FIG. 3 (b)]. While impact is being performed as shown in FIG. 3 (c), this position
control device 7 creates a state in which the pushing guide 8 is pushed against the
narrow side of the slab 1. The conditions for installing the pushing guide 8 are set
in advance, so that the gap L between the block 3 and the casting slab 1 has a predetermined
length.
[0046] Actually, it is necessary to use the narrow side of the slab 1 during casting as
a standard while performing the position setting, since the gap L between the block
3 and the narrow side of the casting slab 1 depends on the width of the slab 1 that
is being cast. This gap L affects the stroke of the impact device 6. If the stroke
is insufficient, then the impact speed cannot be ensured during impact and sufficient
impact energy cannot be produced. Therefore, when impact begins, the relative positions
of the block 3 and the narrow side of the slab 1 are adjusted in what is called positioning.
[0047] Using the impact-vibration equipment of the present invention, when continuously
casting the slab 1 having a rectangular transverse cross section, soft reduction is
continuously carried out so that the solid fraction at the center in the direction
of thickness f
s is at least 0.1-0.9, and the reduction ratio in the direction of slab thickness is
within 1% per meter of length in the direction of casting, and the equipment continuously
impacts both of the opposing sides of the narrow side of the slab 1 in the direction
of slab width at least one site where the solid fraction at the center in the direction
of thickness f
s is within a range of 0.1-0.9 with a vibration frequency of impact of 4-12 Hz and
an impact energy of 30-150 J.
[0048] The following is an explanation of the reason why the present invention continuously
impacts both of the opposing sides of the narrow side of the slab 1 in the direction
of slab width at at least one site where the solid fraction at the center in the direction
of thickness f
s is within a range of 0.1-0.9.
[0049] The reason is that since bridging of equiaxed crystals or the like occurs at positions
on the casting slab 1 where the solid fraction at the center in the direction of thickness
of the casting slab 1 is 0.1 or higher, equiaxed crystals do not sufficiently form
at positions where the solid fraction at the center in the direction of thickness
of casting slab is less than 0.1, and the impact effect on the casting slab 1 is small.
Another reason is that if the solid fraction at the center in the direction of thickness
of the casting slab 1 exceeds 0.9, then the liquid molten steel no longer readily
vibrates and flows, thus bridging of equiaxed crystals or voids formed by bridging
become difficult to break by impacting the casting slab 1.
[0050] FIG. 4 is a graph illustrating length in the direction of casting and the liquid
core thickness in a region where the solid fraction at the center in the direction
of thickness is 0.1-0.9 in the case of high carbon steel with a thickness of 300 mm
(C = 0.40 mass %) when continuous casting is performed under casting conditions where
the casting speed is 0.75 m/min, and the specific cooling intensity in the secondary
cooling is 0.8 L/kg.
[0051] As shown in FIG. 4, the solid fraction at the center in the direction of thickness
f
s in the range of 0.1-0.9 referred to in this invention forms a long region in the
direction of casting. The double-headed arrows shown in two places in FIG. 4 illustrate
examples of impact plates for imparting impact to the slab being arranged in the respective
positions with the distance being taken from the mold output side.
[0052] The example of the impact plate of FIG. 4 illustrates continuous impact on both of
the opposing sides of the narrow side of the slab 1 in the direction of slab width,
when the solid fraction at the center in the direction of thickness f
s is in the range 0.4-0.8.
[0053] FIG. 5 is a graph illustrating length of the slab 1 measured in the direction of
casting and the liquid core thickness in a region where the solid fraction at the
center in the direction of thickness f
s is 0.1-0.9 in the case of medium carbon steel with a thickness of 250 mm (C = 0.06
mass %) when continuous casting is performed under conditions where the casting speed
is 1.0 m/min, and the specific cooling intensity in the secondary cooling is 0.8 L/kg.
[0054] The double-headed arrows shown in the two places in FIG. 5 illustrate examples of
impact plates for imparting impact to the slab being arranged in a position at the
distance of these two places from the mold output side. The example of the impact
plate of FIG. 5 illustrates continuous impact on both of the opposing sides of the
narrow side of the slab 1 in the direction of slab width when the solid fraction at
center in the direction of thickness f
s is in the range 0.25-1.0, which range also includes the range 0.25-0.9.
[0055] In the present invention, soft reduction is continuously carried out on the casting
slab, so that the solid fraction at the center in the direction of thickness f
s is in the range 0.1-0.9 and so that the reduction ratio in the direction of slab
thickness is within 1% per meter of length in the direction of casting. The reason
for this is that when the inventors took into consideration the amount of solidification
shrinking and the amount of heat shrinking in computing the roll gap (the amount of
roll gap squeezing in the direction of casting) of the paired pinch rolls 2a, 2b,
the effective range for decreasing center segregation is such that the reduction ratio
in the direction of slab thickness is within about 1% per meter of length in the direction
of casting.
[0056] That is to say, if reduction is carried out with the reduction ratio in the direction
of slab thickness greatly exceeding 1% per meter of length in the direction of casting
and at a low solid fraction range, then strain at the solid-liquid interface greatly
increases and internal cracking readily occurs. When soft reduction is carried out
continuously, internal cracking starts to be suppressed, however if reduction is carried
out at least at a level in which the amount of solidification shrinkage is offset
it is sufficient. In this case, the reduction ratio in the direction of thickness
of the slab 1 is within 1% per meter of length in the direction of casting.
[0057] Moreover, in the present invention, the narrow side of the slab is subjected to continuous
impact, rather than the wide side of the slab. The slab readily undergoes bulging
between the rolls on the wide side, and if impact vibration is applied to a bulging
wide side, then fluctuation in the surface level of molten steel in the mold is encouraged
on the upstream side. Furthermore, it is impossible to apply a large amplitude vibration
to the slab thickness center, since the slab 1 is bulging. Additionally, provision
of the impact imparting means causes the drawback of interference with the spraying
position for secondary cooling of the slab between the rolls, thus making it impossible
to continuously apply impact.
[0058] By contrast, if impact vibration is applied to the narrow side of the slab, a large
change in volume will not occur in comparison to the wide side, even if dislocation
occurs due to the impact. Thus, the above described problems do not arise, as do in
the case when impact vibration is applied to the wide side. Moreover, few installation
problems occur when setting up the impact imparting means.
[0059] For example, if the slab width is set at 2,300 mm and the width of the block 3 is
set at 200 mm, and if the impact vibration is to be applied to the wide side if the
slab, then the site where impact vibration can be applied is 200 mm in the direction
of casting. By contrast, if the impact vibration is to be applied to the narrow side
of the slab, the site where the impact vibration can be applied is on the order of
2,300 mm in the direction of casting, for example, as long as the length of the impact
plate is sufficiently maintained. Therefore, if impact vibration is applied to the
narrow side of the slab, then the volume change is on the order of 1/11.5.
[0060] Moreover, in the present invention, the reason why the vibration frequency of impact
is set at 4-12 Hz during impact is that if the vibration frequency of impact is less
than 4 Hz, then the impact energy is not sufficiently transmitted to the liquid core
of the slab, so there is little center segregation decreasing effect.
[0061] Higher frequencies are desirable from the standpoint of imparting impact energy,
but if an air cylinder system is used as a means for imparting impact energy, then
turbulence develops in the vibration waveform as the impact frequency increases. Moreover,
when the slab 1 undergoes impact, sufficient effects are achieved if impact is applied
up to 12 Hz, depending on the deformation characteristics of the slab 1. In addition,
if the operator intends to increase the impact frequency, the air supply pressure
must be raised, which presents concerns regarding the effect of air supply pressure
on peripheral equipment due to the impact. Thus, the upper limit of the range within
which center segregation can be decreased is set at 12 Hz.
[0062] In the present invention, the impact energy is set at 30 J -150 J. This is because
if impact energy exceeding 150 J is applied, then peripheral equipment installed in
the continuous casting machine can be damaged. If impact energy is applied above the
necessary level, then the durability of the impact device 6 itself can be compromised.
[0063] On the other hand, if the impact energy is less than 30 J, then the impact vibration
is not sufficiently propagated from the narrow side of the slab 1 to the slab interior
in the vicinity of the center in the direction of slab width.
[0064] The impact energy E (J) can be obtained from the equation E = 0.5 × M × V
2, where M (kg) is the weight of the block 3, and V (m/sec) is the impact speed of
the block 3 moving toward the slab 1. Therefore, the impact energy can be changed
either by changing the weight of the block 3, or by changing the impact speed of the
block 3 moving toward the slab 1. However, the impact frequency is of particular importance
since bridging cannot be completely suppressed, particularly when there is a high
solid fraction at the final stage of solidification, even if a high impact energy
is applied several times every minute.
[0065] The range of vibration frequency of impact established for the present invention
does not change with blooms or slabs of different slab widths. However, the optimal
impact energy changes, since the volumes of liquid held by blooms and slabs can differ.
[0066] When soft reduction is performed during continuous casting using the impact-vibration
equipment of the present invention, in a range from the upstream side to the downstream
side at a position where the surface of the slab 1 is impacted, it is desirable for
the reduction ratio to be 0.5-2.5 mm per meter of length in the direction of casting,
where the solid fraction at center in the direction of thickness f
s of the slab 1 is 0.1-0.9.
[0067] Accordingly, in the present invention, when subjecting the slab 1 to soft reduction,
vibrations due to impact can be sufficiently propagated to the interior of the slab
1, by applying to the slab 1 impact vibration which satisfies the optimal impact conditions,
thereby making it possible to achieve an even greater segregation decreasing effect.
WORKING EXAMPLES
[0068] Following is an explanation of the results of experiments performed to test the present
invention.
[0069] An impact device such as that shown in FIG. 1 was installed in two pairs of pinch
rolls in the direction of casting. High carbon steel with a composition shown in Table
2 below was cast into blooms or slabs. The size was 250-310 mm thick and 425 mm or
2,300 mm wide. The casting speed was set at 0.70 m/min or 0.75 m/min.
TABLE 2
| |
[C] |
[Si] |
[Mn] |
[P] |
[S] |
Residue |
| High carbon steel |
0.26-1.00 |
0.02-2.00 |
0.10-3.00 |
0.08 or less |
0.02 or less |
Fe and impurities |
| |
|
|
|
|
(Unit: Mass %) |
[0070] With the solid fraction at the center in the direction of thickness set at 0.1-0.9
during soft reduction, slabs were subjected to soft reduction at a ratio of 1.0 mm
per meter of length in the direction of casting. Uniform conditions were set such
that the specific cooling intensity was 0.8 L/kg in secondary cooling.
[0071] Using an air cylinder type impact device, two sites on both sides of the narrow side
of a slab at a position containing a liquid core were continuously impacted at a frequency
of 4 Hz or 6 Hz (240 times/min or 360 times/min) so that the amplitude of vibrations
at the impact surface was ± 3 mm.
[0072] The impact conditions were set such that the block weight was 450 kg and the impact
speed was about 0.47 m/sec or 0.71 m/sec (the impact energy was 50 J or 114 J). The
shape of the surface of the block attached to the front end of the impact device that
comes into contact with the bloom or the slab had a width in the direction of slab
thickness of about 200 mm, and a length in the direction of casting of about 1,100
mm.
[0073] In casting tests, slab samples were removed, and test pieces were taken from these
samples at positions corresponding to the thickness of a transverse cross section
and corresponding to the center in the direction of width, on the order of 10 mm in
the direction of thickness, including the center in the direction of thickness, 200
mm in the direction of width, and 15 mm in the direction of casting.
[0074] Using these test pieces, the carbon concentration was analyzed by removing chips
from 26 sites at positions corresponding to the center in the direction of slab thickness,
with a drill blade 2 mm in diameter at a pitch of 7 mm. The resulting carbon concentration
(mass %) was divided by the carbon concentration of molten steel in the ladle, resulting
in the ratio C/C0, and the maximum values for this ratio (maximum center segregation
ratio) were obtained.
[0075] The test conditions are given in Table 3 below. This test was performed on: an inventive
example (high carbon steel C) to which impact vibration was applied between pinch
rolls using the impact-vibration equipment of the present invention; a comparative
example (high carbon steel B) to which impact vibration was applied at a segment,
using impact-vibration equipment disclosed in Japanese Patent Application No.
2006-53057; and a comparative example (high carbon steel A) produced without applying impact
vibration.
TABLE 3
| Test Piece |
Impact Vibration |
Casting Speed |
Impact Vibration Conditions |
Slab Dimensions |
| Solid Fraction |
Vibration Frequency of Impact |
Impact Energy |
| Comparative Example (High carbon steel A) |
None |
0.7 m/min |
0.1-0.9 |
- |
- |
310 × 425 mm |
| Comparative Example (High carbon steel B) |
Impact vibration at segment |
0.7 m/min |
0.4-0.9 |
4 Hz |
50 J |
310 × 425 mm |
| Inventive Example (High carbon steel C) |
Impact vibration between pinch rolls |
0.75 m/min |
0.4-0.8 |
6 Hz |
114 J |
300 × 2,300 mm |
[0076] The test results are shown in FIG. 6. In tests where impact vibration was applied,
no significant differences were found in the size of the maximum center segregation
in any of the samples, and the maximum center segregation ratio was a favorable 1.15
or less in all cases. On the other hand, in tests where impact vibration was not applied,
there were cases in which the maximum center segregation ratio exceeded 1.15, as the
slab width increased. In evaluating test results, a maximum center segregation ratio
of 1.15 or less was considered good, and results exceeding that value were considered
poor.
[0077] The present invention is not limited to the foregoing examples, and the embodiments
can of course be suitably modified, as long as they are within the scope of the technical
ideas recited in the claims.
[0078] For example, in the above description, an air cylinder was used as the impact device
6. However, any method may be used, as long as it is able to drive the block 3. Examples
include a hydraulic cylinder, a method using a leaned cam, or a method using a spring.
INDUSTRIAL APPLICABILITY
[0079] The present invention can be applied not only to high carbon steel slabs as described
in the examples, but also to continuous casting of other types of steel, such as medium
carbon steel slabs and low carbon steel slabs.