TECHNICAL FIELD
[0001] The present invention relates to an edge bending method and apparatus of a steel
plate for subjecting widthwise edges of the steel plate to edge bending several times
separately in a longitudinal direction of the steel plate. Furthermore, the present
invention relates to a method and a facility for manufacturing a steel pipe by forming
a steel plate subjected to edge bending into a cylindrical shape, butting the widthwise
edges to each other, and joining the butted widthwise edges of the steel plate by
welding.
BACKGROUND ART
[0002] For manufacture of a large-diameter steel pipe used for a line pipe or the like,
there has been used a method in which a steel plate having a predetermined length,
width, and thickness is formed by press working into a cylindrical shape having a
pipe axis direction in the longitudinal direction of the steel plate, and then the
widthwise edges thereof are butt-joined to each other. For the sake of easy formation
into a cylindrical shape and appropriate pipe shape, edge bending (crimping) that
imparts a predetermined curvature to the widthwise edges of the steel plate is performed
prior to the formation into a cylindrical shape.
[0003] Such an edge bending is performed in the following manner: a steel plate is arranged
between a lower die and an upper die that has a curvature depending on a pipe diameter,
and the lower die is lifted by a hydraulic cylinder such that the widthwise edges
of the steel plate are pressed against the upper die. However, since the steel plate
is longer than the effective length of the dies, the steel plate cannot be pressed
across the entire length in a single pressing. Therefore, there has been adopted a
method in which edge bending is performed several times (e.g., three to four times)
on the widthwise edges of the steel plate while intermittently feeding the steel plate
in the longitudinal direction to perform edge bending across the entire length.
[0004] Patent Literatures 1 to 3 disclose a method for obtaining a preferable shape at a
butted portion. Patent Literature 1 specifies a feed length b depending on the thickness
or strength of a steel plate. Patent Literature 2 specifies a length Lc of a region
to be bent depending on the thickness or strength of a steel plate. Patent Literature
3 specifies a radius of curvature R1 of an upper die, a horizontal distance u relative
to the center of the curvature of the upper die to an end of a steel plate, and a
pressing force w depending on the thickness or strength of the steel plate. Patent
Literature 4 proposes a method of manufacturing a steel pipe in which the variation
in shape of a butted portion is small on the basis of the information of the strength
of a steel plate. Patent Literature 5 proposes a method for performing edge bending
continuously.
[0005] Patent Literature 6 discloses a method including a U-ing press process for bending
a steel plate over the whole length at the same time in manufacture of a steel pipe,
in which a transition part that is tapered toward the end of the contact face with
the steel plate is formed on the both pipe axis direction end portions of the lower
rocker shoe of the rocker die in contact with the outer side surface of the steel
plate, in order to prevent from locally contacting a portion causing opening deformation
at the longitudinal end portion.
CITATION LIST
PATENT LITERATURE
SUMMARY OF INVENTION
TECHNICAL PROBLEM
[0007] Patent Literatures 1 to 4 are, however, all aimed at optimization of the shape at
a certain cross section of a steel plate and do not take into consideration variation
in the edge bending shape of the steel plate in the longitudinal direction. In particular,
in the case of a steel plate having a large thickness and high strength, the edge
bending shape is sometimes not uniform in the longitudinal direction of the steel
plate, resulting in defective welding at a butted portion or a defective shape of
a butted portion of a steel pipe product. Furthermore, in the method described in
Patent Literature 5, it is unclear that a leading end portion, which has no steel
plate to the front therefrom, or a trailing end portion, which has no steel plate
to the rear therefrom, has the same bending shape as at the middle portion in the
longitudinal direction. Moreover, introduction of a new facility is needed. The method
described in Patent Literature 6 relates to a method for preventing the opening deformation
and does not take into consideration the case of subjecting a part of the steel plate
in the longitudinal direction to bending several times while intermittently feeding
the steel plate along the longitudinal direction.
[0008] It is an object of the present invention to solve the problems inherent to the aforementioned
conventional techniques and to obtain an edge bending shape of a steel plate with
less variation across the entire length, without introducing a new facility.
MEANS FOR SOLVING THE PROBLEMS
[0009] The inventors have studied how the edge bending shape is varied in a longitudinal
direction of the steel plate to figure out the cause thereof, and as a result, arrived
at the present invention. A first aspect is an edge bending method of a steel plate
using an edge bending apparatus of a steel plate including: a pair of dies configured
to be arranged corresponding to a widthwise edge of a steel plate; an actuator configured
to clamp the pair of dies with a predetermined pressing force; and a conveyance mechanism
configured to convey the steel plate in a direction along a longitudinal direction
of the steel plate as a conveyance direction, in which the widthwise edge of the steel
plate is subjected to edge bending across an entire length by performing edge bending
of the widthwise edge of the steel plate several times by the pair of dies while the
steel plate is intermittently conveyed by the conveyance mechanism, and one of the
pair of dies that contacts a surface positioned at the outer side of edge bending
of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending, and edge bending is performed
on the widthwise edge of the steel plate with a center of the flat part in the conveyance
direction being displaced to a delivery side in the conveyance direction relative
to a center of the pressing force generated by the actuator in the conveyance direction.
[0010] A second aspect is the edge bending method of a steel plate according to the first
aspect, in which the die that contacts the surface positioned at the outer side of
edge bending includes a transition part formed of a curved surface and provided adjacent
to the flat part at least on a delivery side in the conveyance direction, and the
flat part and the transition part are connected to have a common tangent line.
[0011] A third aspect is the edge bending method of a steel plate according to the first
or second aspect, in which a leading end portion of the steel plate in the conveyance
direction is at a position corresponding to a front end of the flat part in the first
pass of edge bending the widthwise edge of the steel plate.
[0012] A fourth aspect is the edge bending method of a steel plate according to any one
of the first to third aspects, in which a trailing end portion of the steel plate
in the conveyance direction is at a position corresponding to a rear end of the flat
part in the final pass for bending the widthwise edge of the steel plate.
[0013] A fifth aspect is a method for manufacturing steel pipe including: an edge bending
process of a steel plate using an edge bending apparatus of a steel plate provided
with a pair of dies configured to be arranged corresponding to a widthwise edge of
a steel plate, an actuator configured to clamp the pair of dies with a predetermined
pressing force, and a conveyance mechanism configured to convey the steel plate in
a direction along with a longitudinal direction of the steel plate as a conveyance
direction, in which the widthwise edge of the steel plate is subjected to edge bending
across an entire length by performing edge bending of the widthwise edge of the steel
plate several times by the pair of dies while the steel plate is intermittently conveyed
by the conveyance mechanism; a cylinder-forming process in which the steel plate with
the widthwise edges subjected to edge bending is formed into a cylindrical shape and
the widthwise edges of the steel plate are butted with each other; and a joining process
in which the butted widthwise edges of the steel plate are welded, and one of the
pair of dies that contacts a surface positioned at the outer side of edge bending
of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending, and edge bending is performed
on the widthwise edge of the steel plate with a center of the flat part in the conveyance
direction being displaced to a delivery side in the conveyance direction relative
to a center of the pressing force generated by the actuator in the conveyance direction.
[0014] A sixth aspect is an edge bending apparatus of a steel plate including: a pair of
dies configured to be arranged corresponding to a widthwise edge of a steel plate;
an actuator configured to clamp the pair of dies with a predetermined pressing force;
and a conveyance mechanism configured to convey the steel plate in a direction along
a longitudinal direction of the steel plate as a conveyance direction, in which the
widthwise edge of the steel plate is subjected to edge bending across an entire length
by performing edge bending of the widthwise edge of the steel plate several times
by the pair of dies while the steel plate is intermittently conveyed by the conveyance
mechanism, and one of the pair of dies that contacts a surface positioned at the outer
side of edge bending of the widthwise edge of the steel plate to be bent includes
a flat part that contacts the surface positioned at the outer side of edge bending,
and a center of the flat part in the conveyance direction is displaced to a delivery
side in the conveyance direction relative to a center of the pressing force generated
by the actuator in the conveyance direction.
[0015] A seventh aspect is the edge bending apparatus of a steel plate according to the
sixth aspect, in which the die that contacts the surface positioned at the outer side
of edge bending includes a transition part formed of a curved surface provided adjacent
to the flat part at least on a delivery side in the conveyance direction, and the
flat part and the transition part are connected to have a common tangent line.
[0016] An eight aspect is a facility for manufacturing a steel pipe including: an edge bending
apparatus of a steel plate provided with a pair of dies configured to be arranged
corresponding to a widthwise edge of a steel plate, an actuator configured to clamp
the pair of dies with a predetermined pressing force, and a conveyance mechanism configured
to convey the steel plate in a direction along a longitudinal direction of the steel
plate as a conveyance direction, in which the widthwise edge of the steel plate is
subjected to edge bending across an entire length by performing edge bending of the
widthwise edge of the steel plate several times by the pair of dies while the steel
plate is intermittently conveyed by the conveyance mechanism; a cylinder-forming apparatus
configured to form the steel plate with the widthwise edges subjected to edge bending
into a cylindrical shape and butt the widthwise edges of the steel plate with each
other; and a joining apparatus configured to weld the butted widthwise edges of the
steel plate, and one of the pair of dies that contacts a surface positioned at the
outer side of edge bending of the widthwise edge of the steel plate to be bent includes
a flat part that contact the surface positioned at the outer side of edge bending,
and a center of the flat part in the conveyance direction is displaced to a delivery
side in the conveyance direction relative to a center of the pressing force generated
by the actuator in the conveyance direction.
[0017] A ninth aspect is the facility for manufacturing a steel pipe according to the eight
aspect, in which the die that contacts the surface positioned at the outer side of
edge bending includes a transition part formed of a curved surface provided adjacent
to the flat part at least on a delivery side in the conveyance direction, and the
flat part and the transition part are connected to have a common tangent line.
EFFECT OF THE INVENTION
[0018] According to the present invention, one of a pair of dies that contacts a surface
positioned at the outer side of edge bending of a widthwise edge of a steel plate
to be bent includes a flat part that contacts the surface positioned at the outer
side of edge bending, and edge bending is performed on the widthwise edge of the steel
plate with a center of the flat part in the conveyance direction being displaced to
a delivery side in the conveyance direction relative to a center of the pressing force
in the conveyance direction generated by the actuator, whereby a center of bending
deformation force moves closer to the center of the pressing force. As a result, inclination
of the die during the edge bending can be suppressed, and the variation of the amount
of bending deformation of the widthwise edge of the steel plate in the longitudinal
direction can be reduced.
BRIEF DESCRIPTION OF THE DRAWINGS
[0019]
FIG. 1 is a view schematically explaining a method and facility for manufacturing
a steel pipe according to an embodiment of the present invention.
FIG. 2 is a plan view illustrating an example of a steel plate subjected to edge bending.
FIG. 3 is a schematic view illustrating an edge bending apparatus of a steel plate
according to an embodiment of the present invention.
FIG. 4 is a cross-sectional view in a width direction illustrating a state before
edge bending by a press mechanism of the edge bending apparatus of a steel plate of
FIG. 3.
FIG. 5 is a cross-sectional view in a width direction illustrating a state during
edge bending by a press mechanism of the edge bending apparatus of a steel plate of
FIG. 3.
FIG. 6(a) is a cross-sectional view in a conveyance direction illustrating a press
mechanism of a conventional edge bending apparatus of a steel plate in a state before
the edge bending, and FIG. 6(b) illustrates that in a state during the edge bending.
FIG. 7 is a graph illustrating a change of a shape of a steel plate by edge bending.
FIG. 8(a) is a view illustrating a relationship between the center of pressing force,
the center of a flat part, and the center of bending deformation force in the case
of the first edge bending using the conventional edge bending apparatus of a steel
plate illustrated in FIG. 6, and FIG. 8(b) is a schematic view illustrating a state
in which a lower die is inclined due to a relationship between the center of pressing
force, the center of a flat part, and the center of bending deformation force.
FIG. 9(a) is a view illustrating a relationship between the center of pressing force,
the center of a flat part, and the center of bending deformation force in the case
of the second edge bending using the conventional edge bending apparatus of a steel
plate illustrated in FIG. 6, and FIG. 9(b) is a schematic view illustrating a state
in which a lower die is inclined due to a relationship between the center of pressing
force, the center of a flat part, and the center of bending deformation force.
FIG. 10 is a view illustrating a relationship between the center of pressing force,
the center of a flat part, and the center of bending deformation force in the case
of the first edge bending using an edge bending apparatus of a steel plate according
to an embodiment of the present invention.
FIG. 11 is a view illustrating a relationship between the center of pressing force,
the center of a flat part, and the center of bending deformation force in the case
of the second edge bending using an edge bending apparatus of a steel plate according
to an embodiment of the present invention.
FIG. 12(a) is a view illustrating a relationship between the center of pressing force,
the center of a flat part, and the center of bending deformation force in the case
of the final edge bending using an edge bending apparatus of a steel plate according
to an embodiment of the present invention, and FIG. 12(b) is a schematic view illustrating
a state in which a lower die is inversely inclined due to a relationship between the
center of pressing force, the center of a flat part, and the center of bending deformation
force.
FIG. 13 is a cross-sectional view along a conveyance direction illustrating a lower
die of another example in which a transition part, which can preferably be used in
the present invention, is provided adjacent to a flat part.
FIG. 14 is a view explaining peaking.
FIG. 15 is a view explaining a bending shape and peaking.
EMBODIMENT FOR CARRYING OUT THE INVENTION
[0020] An embodiment of the present invention is described in detail below on the basis
of the drawings. Similar constituent elements are designated with the same reference
numerals and will not be elaborated as appropriate in the description below. Note
that, in the description, "front" or "front side" indicates a "delivery side" or a
"direction from entry side to delivery side" in a conveyance direction of a steel
plate in an edge bending apparatus described below, and "rear" or "rear side" indicates
the opposite direction.
[0021] FIG. 1 schematically illustrates a method and a facility for manufacturing a steel
pipe according to an embodiment of the present invention for manufacturing a steel
pipe from a steel plate which is cut into a predetermined dimension. First, a steel
plate S cut into a predetermined dimension is subjected to beveling working on a side
surface thereof by an edge miller 10 or an edge planer. In the illustrated example,
tab plates St are welded to a leading end portion (longitudinal front side end portion)
Sa and a trailing end portion (longitudinal rear side end portion) Sb of a steel plate
S. However, the tab plates St may not be provided. Next, edge bending is performed
by an edge bending apparatus (crimping) 20 according to an embodiment of the present
invention (edge bending process), and a cylindrical shape is formed by a cylinder-forming
apparatus 30 (cylinder-forming process). The cylinder-forming apparatus 30 is not
limited to those including a U-ing press 30A that first forms the steel plate S subjected
to the edge bending into a U shape, and an O-ing press 30B that then forms the steel
plate S into an O shape (cylindrical shape). The cylinder-forming apparatus 30 may
be a bending press 30C including a feed mechanism that feeds the steel plate S in
the width direction and gradually forms the steel plate S into a cylindrical shape
as a final shape by sequentially feeding the steel plate S in the width direction
and performing three-point bending. Next, the widthwise edges of the steel plate S,
which are butted with each other as a result of the cylindrical formation, are temporarily
welded from the outer surface and then welded by submerged arc welding or the like
from the inner surface and the outer surface by a joining apparatus 40 (joining process).
Then, the diameter of the steel pipe S' is expanded by a mechanical expander 50 to
remove the residual stress, and the steel pipe S' is finished so as to have a predetermined
outer diameter and dimension (pipe expansion process). It is noted that other processing
such as cleaning, various inspection and bead grinding may be performed in each process
or between the processes.
[0022] The edge bending apparatus 20 of a steel plate according to an embodiment of the
present invention and the edge bending method of a steel plate using the same are
described in more detail. FIG. 2 illustrates an example of the steel plate S prior
to the edge bending. The width of the steel plate S has a wide range, e.g., from 1200
mm to 5100 mm, depending on the outer diameter of a steel pipe product. Furthermore,
a steel plate often has a length of about 12 m, which is a standard length of a line
pipe. Tab plates St are welded to each widthwise edge of a leading end portion Sa
and a trailing end portion Sb of the steel plate S, which becomes a steel pipe body,
in the longitudinal direction. However, the tab plates St may be absent.
[0023] FIG. 3 illustrates a schematic configuration of the edge bending apparatus 20 of
a steel plate. The edge bending apparatus 20 of a steel plate includes a conveyance
mechanism 21 that conveys the steel plate S in a direction along with the longitudinal
direction thereof as a conveyance direction 1, a press mechanism 22A that bends a
widthwise edge Sc, which is on a left side when a delivery side 3 in the conveyance
direction is the front side, into a predetermined curvature, a press mechanism 22B
that bends a widthwise edge Sd on a right side into a predetermined curvature, and
a space adjustment mechanism, which is not illustrated, that adjusts a space between
the right and left press mechanisms 22A and 22B depending on the width of the steel
plate S on which the edge bending is performed. The conveyance mechanism 21 includes
a plurality of conveyance rolls 21a, which are arranged before and after the press
mechanisms 22A and 22B. The roll shafts of the conveyance rolls 21a are arranged in
a direction perpendicular to the conveyance direction of the steel plate S and are
configured to be rotated at a synchronized velocity by a motor and a transmission
mechanism, which are not illustrated.
[0024] FIG. 4 illustrates a widthwise cross section of the press mechanism 22A that bends
the left widthwise edge Sc of the steel plate S when viewed in a direction from an
entry side 2 to a delivery side 3 of the conveyance direction 1 of the steel plate
S. Note that the press mechanism 22A and the press mechanism 22B are bilaterally symmetric
and have the same configuration, and accordingly, a detailed illustration of the press
mechanism 22B is omitted. The press mechanism 22A and 22B include an upper die 23
and a lower die 24, which are a pair of dies arranged opposite to each other in a
vertical direction, a hydraulic cylinder 26, which is an actuator that lifts the lower
die 24 together with a tool holder 25 and performs clamping with a predetermined pressing
force, and a holding mechanism 27 that releasably holds the steel plate S at each
widthwise inner side of the upper die 23 and the lower die 24. Note that the length
of the lower die 24 and the upper die 23 in the longitudinal direction of the steel
plate S is shorter than the length of the steel plate S. It is configured such that
edge bending is performed several times with the steel plate S being moved (intermittently
fed) in the longitudinal direction by the conveyance mechanism 21 to provide edge
bending on the widthwise edges Sc and Sd of the steel plate S across the entire length.
[0025] FIG. 5 is a cross-sectional view in the width direction at the same position as in
FIG. 4 illustrating a state in which the lower die 24 is clamped by being lifted by
the hydraulic cylinder 26. When the hydraulic cylinder 26 is advanced from a state
before the edge bending indicated by the dotted line, the lower die 24 is lifted and
brought into the position of the solid line. The widthwise edges Sc and Sd of the
steel plate S are bent into a shape following the arc-shaped pressing face of the
upper die 23. The width on which the edge bending is performed varies with the width
of the steel plate S and is generally about 100 mm to 400 mm. Herein, an example is
given of the case where the holding mechanism 27 for holding the steel plate S during
the edge bending is performed, but is not limited to the presence or absence of the
holding mechanism 27.
[0026] FIG. 6 is a cross-sectional view along with the conveyance direction 1 illustrating
a state in which the widthwise edges Sc and Sd of the steel plate S are subjected
to edge bending. The steel plate S is carried in from the left side of the drawing
and carried out to the right side. The lower die 24 includes a flat part 24a that
mainly provides the edge bending. Within the portion facing the upper die 23, the
flat part 24a indicates a portion that is extended linearly along the conveyance direction
1 and is planar in the cross section along with the conveyance direction, but does
not mean that it is planar in a widthwise cross section. The shape of the flat part
24a in the widthwise cross section is not particularly limited, and may be an arc
shape or may be a straight shape that is inclined to face inward in the width direction.
In order to reduce the number of times of edge bending, the effective length of the
lower die 24, i.e., the length of the flat part 24a is set to be larger than the width
that is subjected to the edge bending. The flat part 24a has, for example, a length
of 3 m to 5 m, which is a size about 10 times greater than the width that is subjected
to the edge bending. Hence, typically, a plurality of hydraulic cylinders 26 for lifting
the lower die 24 is arranged along the conveyance direction. In this case, in general,
a combination of a piston-type hydraulic cylinder 26 that generates a thrust force
in two directions: upward and downward and a ram-type hydraulic cylinder 26 that generates
a thrust force only during upward movement is used. In the illustrated example, the
piston-type hydraulic cylinder 26 is arranged in a middle in the conveyance direction
1 and the ram-type hydraulic cylinders 26 are arranged before and after the piston-type
hydraulic cylinder 26. Conventionally, for uniform application of pressing force P,
the flat part 24a of the lower die 24 is designed such that a center C1 in the conveyance
direction 1 of flat part 24a the matches a center C2 of the pressing force P by the
hydraulic cylinders 26.
[0027] FIG. 6(a) illustrates a state in which the widthwise edges Sc and Sd of the steel
plate S are bent by the press mechanisms 22A and 22B and then the steel plate S is
conveyed a predetermined conveyance distance by the conveyance mechanism 21. This
conveyance distance is set to be smaller than the length of the flat part 24a of the
lower die 24. Thus, a rear end of the portion subjected to edge bending is positioned
on the flat part 24a of the lower die 24, and a transition between the already formed
portion and a non-formed portion is unfailingly bent at the next edge bending. The
steel plate S is arranged such that a rear end portion of the portion already subjected
to edge bending is positioned on the flat part 24a as indicated by the dotted line
in FIG. 6(b), and the hydraulic cylinders 26 lift the lower die 24 to perform edge
bending of the widthwise edges Sc and Sd of the steel plate S as indicated by the
solid lines. At this time, a range that has been bent in the previous process is also
bent again for its springback amount, while bending occurs at a portion on the entry
side 2 (left side in the drawing) of the steel plate S, which is not positioned on
the flat part 24a of the lower die 24. As one example, FIG. 7 illustrates results
obtained when the edge bending is performed with respect to a range of 170 mm at the
widthwise edges of the steel plate S having a plate width of 2755 mm × a plate thickness
of 28.9 mm and the shape is examined. The flat part 24a of the lower die 24 has a
length of 3 m, and the edge bending angle is measured when the first edge bending
is performed with respect to the leading end portion of 2.8 m from the leading end
of the steel plate. The steel plate is then conveyed 2 m, and the edge bending angle
is again measured when the second edge bending is performed. Here, the edge bending
angle is determined from a difference between an inclination angle in a range of 20
mm at the widthwise edge and an inclination angle of a widthwise middle portion measured
by an inclinometer. In FIG. 7, the edge bending angle in the first edge bending is
plotted as • and the bending angle in the second edge bending is plotted as ▲. Moreover,
the range that of the flat part 24a of the lower die in the first edge bending is
indicated as Ra1, and the range of the flat part 24a of the lower die in the second
edge bending is indicated as Ra2. In the first edge bending, the edge bending angle
is large (Da) at the leading end portion Sa of the steel plate S, and bending also
occurs at a portion that does not contact the flat part 24a on the entry side 2 for
a length of about 0.6 m. In the second edge bending, bending is further applied to
the portion that has been bent in the first edge bending, and the edge bending angle
becomes larger (Dc) toward the delivery side 3. On the entry side 2, the edge bending
angle is slightly large in the vicinity of the end of the flat part 24a. Similar to
the first time, bending also occurs at the portion that does not contact the flat
part 24a for a length of about 0.6 m. At this time, the amount of lifting of the lower
die 24 is larger by 2 mm on the delivery side 3. It is presumed that an inclination
of 0.04 degrees is generated during the edge bending such that the leading end portion
side is inclined upward (rotation in pitching direction).
[0028] Further study is conducted to unravel the cause of this inclination. FIG. 8(a) schematically
illustrates the deformation of the steel plate S and distribution of the bending deformation
force Df (force against the pressing force P in edge bending; hereinafter also simply
referred to the "deformation force") at the time of the first edge bending. The deformation
force Df is absent on the delivery side 3 where the steel plate S is absent, while
the deformation force Df occurs on the entry side 2 even in a portion that is not
positioned on the flat part 24a. Therefore, a center C3 of the deformation force Df
is at a position displaced to the entry side 2 relative to the center C1 of the flat
part 24a in the conveyance direction 1. FIG. 9(a) illustrates the case of the second
edge bending. Since the steel plate S is present on the delivery side 3, the deformation
force Df also occurs on the delivery side 3. However, the deformation amount is small
as compared to the amount of the springback, and the center C3 of the deformation
force Df is at a position displaced to the entry side 2 relative to the center C1
of the flat part. When the center C1 of the flat part 24a matches the center C2 of
the pressing force P by the hydraulic cylinders 26, as illustrated in FIGS. 8(b) and
9(b), the force that rotates the leading end portion side in the upward direction
(pitching) is applied to the lower die 24, so that the amount of lifting of the lower
die 24 becomes large on the delivery side 3.
[0029] FIGS. 10 and 11 schematically illustrate the deformation of the steel plate S and
the distribution of the deformation force Df in the case where the center C1 of the
flat part 24a of the lower die 24 is shifted only a displacement amount d to the delivery
side 3 relative to the center C2 of the pressing force P according to the present
invention. FIG. 10 illustrates the first edge bending, and FIG. 11 illustrates the
second edge bending. It can be seen that the deformation force Df on the entry side
2 is small and the center C3 of the deformation force Df is positioned close to the
center C2 of the pressing force P. Thus, the inclination (pitching) of the lower die
24 such that the leading end portion is inclined upward during the edge bending can
be suppressed by displacing the center C1 of the flat part 24a to the delivery side
3 relative to the center C2 of the pressing force P.
[0030] The preferable displacement amount d of the center C1 of the flat part 24a with respect
to the center C2 of the pressing force P can be determined in the manner described
below. As illustrated in FIGS. 8 to 11, in the case where the bending deformation
force Df that occurs on the entry side 2 of the flat part 24a varies substantially
lineally, the sum thereof is half of the deformation force Df that occurs in the flat
part 24a. That is, the deformation force Df is applied on the entry side 2 to the
position half a bending deformation length L from the rear end of the flat part 24a.
When the displacement amount d of the center C1 of the flat part 24a is one fourth
of the bending deformation length L on the entry side 2 relative to the rear end of
the flat part 24a, a symmetric force with respect to the center C2 of the pressing
force P by the hydraulic cylinders 26 is applied, so that the inclination of the lower
die 24 can be minimized.
[0031] However, the length L of the bending deformation occurred on the entry side 2 relative
to the rear end of the flat part 24a varies with the amount of edge bending. When
a steel pipe to be manufactured has a small outer diameter, the width of the steel
plate is also small. Therefore, the edge bending angle (a difference between the inclination
angle in a range of 20 mm at the widthwise edge portion and the inclination angle
of the widthwise middle portion) becomes large, and the length L over which the bending
deformation occurs on the entry side 2 becomes large. When the steel plate illustrated
in FIG. 7 has a width of 2755 mm, the length L over which the bending deformation
occurs on the entry side 2 is about 0.6 m, and 150 mm, which is one fourth of 0.6
m, is the optimum displacement amount d. However, when the steel plate has a width
of 1200 mm, the length L over which the bending deformation occurs on the entry side
2 is about 1.0 m, and 250 mm, which is one fourth of 1.0 m, is the optimum displacement
amount d. Accordingly, it is preferable that the displacement amount d of the center
C1 of the flat part 24a with respect to the center C2 of the pressing force P be appropriately
set depending on the width of the steel plate to be subjected to the edge bending.
Specifically, it is preferable that the displacement amount d be set large with an
increase in the edge bending angle.
[0032] The deformation force Df applied on the delivery side 3 is increased as the displacement
amount d is increased. In this case, the amount of lifting on the entry side 2 is
increased, so that the amount of edge bending on the entry side 2 is increased. Therefore,
it is preferable that the displacement amount d be not more than half the length L
over which the bending deformation occurs on the entry side 2. FIG. 12 illustrates
the deformation of the steel plate S and the distribution of the deformation force
Df in the case where the widthwise edges Sc and Sd of the trailing end portion Sb
of the steel plate S are bent with the center C1 of the flat part 24a being displaced
toward the delivery side 3 relative to the center C2 of the pressing force P. In this
case, the center C3 of the deformation force Df is positioned apart relative to the
center C2 of the pressing force P (displaced to the delivery side 3) as compared with
the cases of FIGS. 10 and 11, and the force of rotating the front side of the lower
die 24 downward (pitching) is applied to increase the amount of lifting on the entry
side 2. Accordingly, it is desirable that the upper limit of the displacement amount
d be determined such that the edge bending does not become excessively large at the
trailing end portion Sb side of the steel plate S.
[0033] Thus, in the edge bending apparatus 20 of a steel plate of the present embodiment
and the edge bending method of a steel plate using the same, the lower die 24, of
the pair of dies 23 and 24, that contacts the surface positioned at the outer side
of edge bending of the widthwise edges Sc and Sd of the steel plate S to be subjected
to edge bending has the flat part 24a that contacts the surface at the outer side
of edge bending of the steel plate S during bending, and the widthwise edges Sc and
Sd of the steel plate S are subjected to edge bending with the center C1 of the flat
part 24a in the conveyance direction 1 being displaced to the delivery side 3 in the
conveyance direction 1 relative to the center C2 of the pressing force P generated
by the hydraulic cylinders 26 in the conveyance direction 1, so that the center C3
of the deformation force Df moves closer to the center C2 of the pressing force P.
As a result, it is possible to suppress inclination of the lower die 24 during the
edge bending and reduce the variation in the amount of bending deformation of the
widthwise edges Sc and Sd of the steel plate S in the longitudinal direction. Furthermore,
shifting of the center C1 of the flat part 24a relative to the center C2 of the pressing
force P can be achieved without introduction of a new facility, for example, by displacing
the lower die 24 to the delivery side 3 in the conveyance direction 1 relative to
the tool holder 25 and the hydraulic cylinders 26 or by displacing the hydraulic cylinders
26 to the entry side 2 in the conveyance direction 1 relative to the lower die 24
in an existing facility.
[0034] Next, description is given of a positional relationship between the leading end portion
(longitudinal front end) Sa and the trailing end portion (longitudinal rear end) Sb
of the steel plate S and the flat part 24a of the lower die 24. Note that the leading
end portion Sa and the trailing end portion Sb of the steel plate S are portions that
become the longitudinal ends of the steel pipe product excluding, in the presence
of the tab plates St, the tab plates St and correspond to the end portions Sa and
Sb of FIG. 2. As illustrated in FIG. 10, when the leading end portion Sa of the steel
plate S is positioned in the rear of the leading end portion of the flat part 24a
in the first (first pass) edge bending, the bending deformation force Df does not
occur on the delivery side 3 relative to the leading end portion Sa of the steel plate
S. Therefore, the center C3 of the deformation force Df is displaced to the entry
side 2 relative to the center C2 of the pressing force P. When the leading end portion
Sa of the steel plate S is brought closer to the leading end portion of the flat part
24a, the displacement amount between the center C3 of the deformation force Df and
the center C2 of the pressing force P becomes small, and it is possible to suppress
the variation in the amount of edge bending. At this time, when the leading end portion
Sa of the steel plate S lies on the delivery side 3 relative to the leading end portion
of the flat part 24a, the portions where the tab plates St are welded are bent insufficiently
and welding is discontinuous at a transition portion from the tab plates St to the
steel plate S. Therefore, it is preferable that the position of the leading end portion
Sa of the steel plate S be at a position not exceeding the leading end portion of
the flat part 24a. Similarly, as illustrated in FIG. 12, when the trailing end portion
Sb of the steel plate S is positioned in the front of the rear end portion of the
flat part 24a in the final (final pass) edge bending, the bending deformation force
Df does not occur on the entry side 2 relative to the trailing end portion Sb of the
steel plate S. Therefore, the center C3 of the deformation force Df is displaced to
the delivery side 3 relative to the center C2 of the pressing force P. When the trailing
end portion Sb of the steel plate S is brought closer to the rear end portion of the
flat part 24a, the displacement amount between the center C3 of the deformation force
Df and the center C2 of the pressing force P becomes small, and it is possible to
suppress the variation in the amount of edge bending. In this case, when the trailing
end portion Sb of the steel plate S is on the entry side 2 relative to the rear end
portion of the flat part 24a, the portions where the tab plates St are welded are
bent insufficiently and welding is discontinuous at a transition portion from the
tab plates St to the steel plate S. Therefore, it is preferable that the position
of the trailing end portion Sb of the steel plate S be at a position not exceeding
the rear end portion of the flat part 24a.
[0035] Next, description is given of another preferable lower die that can be applied to
the present invention. As illustrated in FIG. 9, when there is a portion that has
already been subjected to the edge bending on the delivery side 3, the bending deformation
force Df is absent in this portion at the beginning of the edge bending, and the bending
deformation force Df becomes large on the entry side 2. As a result, the lower die
24 does not contact the steel plate S on the delivery side 3, and the center C3 of
the bending deformation force Df is displaced to the entry side 2 relative to the
center C2 of the pressing force P. Therefore, until the bending deformation occurs
on the delivery side 3, the force of rotating the leading end portion of the lower
die 24 in the upward direction is applied and the amount of lifting is large on the
delivery side 3, so that the edge bending is performed with the lower die 24 being
inclined. As a result, there is a concern that the delivery end portion of the flat
part 24a contacts the portion that has already been subjected to the edge bending,
and as illustrated in FIG. 7 for example, the steel plate portion that contacts the
delivery end portion is deformed at the second edge bending, resulting in forming
a large step with respect to the portion that has been subjected to the first edge
bending on the delivery side 3. Such a steep shape change results in discontinuous
welding at the relevant portion, thereby generating defect or discontinuation of welding.
Therefore, the change of the edge bending angle is desirably smooth (small).
[0036] Thus, with an edge bending method and apparatus of a steel plate according to another
embodiment of the present invention and a method and a facility for manufacturing
a steel pipe, as illustrated in FIG. 13, the lower die 24, which is one of the pair
of dies, may include a transition part 24b formed of a curved surface provided adjacent
to the flat part 24a on the delivery side 3 in the conveyance direction 1. In this
case, it is preferable that the flat part 24a and the transition part 24b be connected
to have a common tangent line. When such a transition part 24b having a curved shape
continuous to the flat part 24a is provided on the delivery side 3, it is possible
to provide a smooth step between the portion of the steel plate S that subjected to
the edge bending in the previous pass and the portion subjected to the edge bending
in the subsequent pass. At this time, the step becomes smoother when the change of
the angle of the transition part 24b is small, i.e., the change of curvature is continuous,
like an involute curve. However, it is necessary that the delivery end portion of
the lower die 24 does not contact the portion that has already been subjected to the
edge bending. A similar transition part 24c may be provided on the entry side 2. In
this case, it is necessary to form the transition part 24c such that the bending deformation
length L (see, for example, FIG. 10) on the rear side relative to the rear end of
the flat part 24a does not become large. The length and angle variation of the transition
part 24c are preferable to be set appropriately in consideration of the above points
and the amount of edge bending that varies with the width of the steel plate S. As
a guide, the length or the angle of the transition part 24c can be changed such that
the range in which the transition part 24c contacts the steel plate S becomes not
more than half the length L over which the bending deformation occurs on the entry
side 2.
[0037] The embodiment of the present invention has been described heretofore on the basis
of the illustrated examples, but the present invention is not limited thereto. Changes,
corrections, additions or the like may be made within the scope of the claims. For
example, in the illustrated examples, descriptions are given of the case where the
edge bending is performed such that the lower die 24 is lifted by the hydraulic cylinders
26 and the widthwise edges Sc and Sd of the steel plate S are pressed against the
upper die 23. However, the lower die 24 may be stationary and the upper die 23 may
be movable such that the upper die 23 is pressed downward and the widthwise edges
Sc and Sd of the steel plate S are pressed against the lower die 24 so as to bend
the plate in the same direction as that of the illustrated example. Furthermore, the
bending may be performed by exchanging the positions of the upper die 23 and lower
die 24 such that the upper side surface of the steel plate is positioned at the outer
side of bending, which is opposite to the illustrated example. In this case, the center
C1 of a flat part of the upper die 23 in the conveyance direction that is positioned
on the outer side of bending is displaced to the delivery side 3 relative to the center
C2 of the pressing force P in the conveyance direction 1. Alternatively, both of the
upper die 23 and the lower die 24 may be configured to be moved in the directions
in which they come closer to or move apart from each other. In this case, the center
C1 of the flat part in the conveyance direction of either one die that is positioned
at the outer side of bending between the upper die 23 and the lower die 24 is displaced
to the delivery side 3 the conveyance direction 1 relative to the center C2 of the
pressing force P. Furthermore, the number of hydraulic cylinders 26 that clamp the
upper die 23 and the lower die 24 is not limited. The clamping may be performed through
the use of one, two, or three or more hydraulic cylinders 26. Furthermore, the actuator
that clamps the upper die 23 and the lower die 24 is not limited to the hydraulic
cylinder 26, but those of a mechanical type that performs clamping by converting the
rotation movement of a motor into reciprocation movement with a crank mechanism or
the like may be used.
EXAMPLE
[0038] In order to ascertain the effect of the present invention, the description is made
below with respect to the study results of the variation in edge bending in the longitudinal
direction performed under different conditions and the influence of the variation
on a subsequent welding process.
EXAMPLE 1
[0039] A steel plate having a tensile strength of 500 MPa, a plate width of 1676 mm × a
plate thickness of 25.4 mm × a length of 12 m including a tab plate having a length
of 400 mm × a width of 100 mm attached to the leading end portion and the trailing
end portion is prepared, and a steel pipe having an outer diameter of 559 mm is manufactured.
An edge bending apparatus of a type that lifts the lower die with three hydraulic
cylinders (actuators) arranged at intervals of 1000 mm is used for edge bending. The
central hydraulic cylinder is of a piston type, and the other two are of a ram type.
The output of the central hydraulic cylinder is half the output of each of the other
hydraulic cylinders, and the output of the three hydraulic cylinders is 15 MN in total.
[0040] The upper die used for the edge bending has a processing face having a radius of
curvature of 200 mm. The flat part of the lower die has a straight shape forming an
angle of 40 degrees with respect to the horizontal surface in the widthwise cross
section. The upper die has the same cross-sectional shape across the entire length.
Three types of lower dies are used: one in which the flat part has a length of 3000
mm and both ends thereof in the longitudinal direction are chamfered at R25 mm (hereinafter
called the "die A"); another including a gentle transition part of R1600 mm formed
continuously from the flat part having a length of 3000 mm on the delivery side 3
(hereinafter called the "die B"); and the other including a gentle transition part
of R1600 mm formed continuously from the flat part having a length of 3000 mm on both
of the entry side 2 and the delivery side 3 (hereinafter called the "die C") .
[0041] With a goal of providing an edge bending angle (a difference between the inclination
angle in a range of 20 mm at the widthwise edge portion and the inclination angle
of the widthwise middle portion) of 33 degrees to a range of 155 mm at the widthwise
edges of the steel plate, the steel plate is subjected to the edge bending four times
while being fed 2600 mm at each time and then subjected to the fifth edge bending
such that the trailing end of the steel plate is stopped at a predetermined position.
After the edge bending, the edge bending angle is measured at a pitch of 0.1 m in
the longitudinal direction. A difference between the maximum and the minimum in the
range of 10 m at the middle in the longitudinal direction is defined as a stationary
portion variation, and a difference between the maximum and the minimum across the
entire length is defined as an entire length variation, and an angular difference
at a step portion where the difference is the largest is assessed as steepness. The
edge bending angle is determined from a difference between the inclination angle in
a range of 20 mm at the widthwise edge portion and the inclination angle of the widthwise
middle portion measured using an inclinometer. Next, U-ing press and O-ing press are
performed for formation into a cylindrical shape, and the widthwise edges of the steel
plate subjected to the edge bending are butted, and then the butted widthwise edges
are welded to manufacture a steel pipe. The peaking Dp of the steel pipe is measured
in the longitudinal direction at a pitch of 0.1 m. The peaking Dp is an index of a
pointed shape of the butted portion and is a difference between an outer diameter
of a regular steel pipe product (i.e., virtual perfect circle Se) and the actual shape
Sp of the steel pipe as illustrated in FIG. 14. As illustrated in FIG. 15, when the
amount of edge bending is excessively large, the butted portion of the steel pipe
has an inwardly dent shape (minus peaking Dp-), while the amount of edge bending is
excessively small, the butted portion of the steel pipe has an outwardly protruding
shape (plus peaking Dp+). Note that, similar to the edge bending angle, regarding
the peaking Dp, a difference between the maximum and the minimum in the range of 10
m at the middle in the longitudinal direction is defined as a stationary portion variation,
and a difference between the maximum and the minimum across the entire length is defined
as an entire length variation.
[0042] The edge bending conditions and the formation results are indicated in Table 1. The
box of the leading/trailing end stop position (stop position of leading end portion
and trailing end portion of the steel plate) indicates "steel plate" when the boundary
between the steel plate and the tab plate is positioned at the delivery side end portion
of the flat part of the lower die at the first edge bending and the boundary between
the steel plate and the tab plate is positioned at the entry side end portion of the
flat part of the lower die at the fifth edge bending. Furthermore, "tab" is indicated
when the entire length of the tab plate is included in the flat part of the lower
die and the end portion of the steel plate is positioned 400 mm inward from the flat
part of the lower die.
Table 1
Condition No. |
Displacement amount d [mm] |
Die |
Leading/trailing end stop position |
Variation in edge bending angle |
Angular difference between portions adjacent to each other [°] |
Number of stop of welding |
Variation in peaking of steel pipe |
Remarks |
Stationary portion [°] |
Entire length [°] |
Stationary portion [mm] |
Entire length [mm] |
1 |
150 |
A |
Steel plate |
1.1 |
1.1 |
1.1 |
0 |
1.2 |
1.2 |
Inventive Example |
2 |
150 |
A |
Tab |
1.0 |
1.4 |
1.0 |
0 |
1.1 |
1.6 |
Inventive Example |
3 |
150 |
B |
Steel plate |
1.0 |
1.0 |
0.6 |
0 |
1.0 |
1.0 |
Inventive Example |
4 |
150 |
B |
Tab |
1.2 |
1.7 |
0.5 |
0 |
1.1 |
1.8 |
Inventive Example |
5 |
150 |
C |
Steel plate |
0.9 |
0.9 |
0.5 |
0 |
0.9 |
0.9 |
Inventive Example |
6 |
150 |
C |
Tab |
1.1 |
1.5 |
0.5 |
0 |
1.0 |
1.6 |
Inventive Example |
7 |
0 |
A |
Steel plate |
2.8 |
2.8 |
2.8 |
4 |
3.1 |
3.1 |
Comparative Example |
8 |
0 |
A |
Tab |
3.2 |
4.8 |
3.2 |
4 |
3.3 |
4.0 |
Comparative Example |
[0043] As indicated in Table 1, under conditions 1 to 6 (inventive examples) in which the
center C1 of the flat part 24a of the lower die in the conveyance direction 1 is set
to be displaced 150 mm (displacement amount d) to the delivery side 3 in the conveyance
direction relative to the center of the central hydraulic cylinder, i.e., the center
C2 of the pressing force P, the variation Dc of the edge bending angle and the variation
of the peaking of the stationary portion are suppressed to about half of those of
conditions 7 and 8 (comparative examples) in which the center C1 of the flat part
24a of the lower die is set to match the center C2 of the central hydraulic cylinder.
[0044] Furthermore, under the conditions 3 and 4 in which the die B provided with a gentle
transition part on the deliver side 3 is used, and conditions 5 and 6 in which the
die C provided with a gentle transition part on both of the entry side and delivery
side is used, the feed boundary is hardly recognizable by sight and the angular difference
between adjacent portions is about half of the variation of the edge bending of the
stationary portion. Meanwhile, under the conditions 1, 2, 7 and 8 in which the die
A is used, the feed boundary is clearly recognizable, and the angular difference between
adjacent portions is the same as the variation of the edge bending angle of the stationary
portion, and the edge bending angle sharply changes as compared with the case where
the die B or die C is used. When comparing the conditions 1, 3 and 5, and conditions
2, 4 and 6, in which only the die used is different, there are little differences
in the variation of the edge bending angle although the variation is smaller in some
cases using the die C, and it can be seen that a transition part may be formed at
least on the delivery side 3.
[0045] Furthermore, under the conditions 1, 3, 5 and 7 in which the longitudinal end of
the steel plate is stopped to be positioned at the end of the flat part, the variation
of the edge bending angle of the stationary portion is the same as the variation of
the edge bending angle of the entire length, and the variation of the peaking of the
stationary portion is the same as the variation of the peaking of the entire length,
and the amount of edge bending is the same across the entire length. Meanwhile, under
the conditions 2, 4, 6 and 8 in which the longitudinal end of the steel plate is positioned
on the inner side of the flat part of the lower die, the amount of edge bending is
large at the end and the variation across the entire length is large. In particular,
under the condition 3 in which the "die B" is used and the longitudinal end of the
steel plate is stopped at the position of the end of the flat part, and the condition
5 in which "die C" is used and the longitudinal end of the steel plate is stopped
at the position of the end of the flat part, the variation of the peaking is 0.9 to
1.0 mm, which is not more than one sixth of ± 3.2 mm, a peaking tolerance required
by API standards, and it can be understood that the shape is superior.
[0046] Under the conditions 7 and 8 that do not satisfy the conditions of the present invention,
as compared with the inventive examples, the variations of the peaking and the edge
bending angle are large. In particular, the large difference in edge bending angle
indicates that an abrupt change occurs at the step of the feed boundary. Since this
abrupt change exceeds the profiling limit of a welding torch, the welding is stopped
urgently.
EXAMPLE 2
[0047] A steel plate having a tensile strength of 550 MPa, a plate width of 2753 mm × a
plate thickness of 38.1 mm × a length of 12 m including a tab plate having a length
of 400 mm × a width of 100 mm attached to the leading end portion and the trailing
end portion is prepared, and a steel pipe having an outer diameter of 914 mm is manufactured.
The upper die used for the edge bending has a processing face having a radius of curvature
of 335 mm. The edge bending is performed with a goal of providing an edge bending
angle of 24 degrees to a range of 180 mm at the widthwise edges of the steel plate.
The other edge bending conditions such as the edge bending apparatus, the lower die,
and the feed amount of the steel plate are the same as those of Example 1. The edge
bending angle is measured after the edge bending, and then the steel plate is formed
into a cylindrical shape by a bending press method, followed by welding to give a
steel pipe.
[0048] The edge bending conditions and the formation results are indicated in Table 2. The
items and descriptions in Table 2 are the same as those of Example 1. As indicated
in Table 2, under conditions 1 to 6 (inventive examples) in which the center C1 of
the flat part 24a of the lower die in the conveyance direction is set to be displaced
150 mm (displacement amount d) to the delivery side 3 in the conveyance direction
1 relative to the center of the central hydraulic cylinder, i.e., the center C2 of
the pressing force P, the variation of the edge bending angle and the variation of
the peaking of the stationary portion are suppressed to about half of those of conditions
7 and 8 (comparative examples) in which the center C1 of the flat part 24a of the
lower die is set to match the center C2 of the central hydraulic cylinder.
Table 2
Condition No. |
Displacement amount d [mm] |
Die |
Leading/trailing end stop position |
Variation in edge bending angle |
Angular difference between portions adjacent to each other [°] |
Number of stop of welding |
Variation in peaking of steel pipe |
Remarks |
Stationary portion [°] |
Entire length [°] |
Stationary portion [mm] |
Entire length [mm] |
1 |
150 |
A |
Steel plate |
1.0 |
1.0 |
1.0 |
0 |
1.1 |
1.1 |
Inventive Example |
2 |
150 |
A |
Tab |
0.9 |
1.2 |
0.9 |
0 |
1.0 |
1.4 |
Inventive Example |
3 |
150 |
B |
Steel plate |
0.9 |
0.9 |
0.5 |
0 |
0.9 |
0.9 |
Inventive Example |
4 |
150 |
B |
Tab |
1.1 |
1.5 |
0.4 |
0 |
1.0 |
1.6 |
Inventive Example |
5 |
150 |
C |
Steel plate |
0.8 |
0.8 |
0.4 |
0 |
0.8 |
0.8 |
Inventive Example |
6 |
150 |
C |
Tab |
1.0 |
1.3 |
0.4 |
0 |
0.9 |
1.4 |
Inventive Example |
7 |
0 |
A |
Steel plate |
2.5 |
2.5 |
2.5 |
3 |
2.7 |
2.7 |
Comparative Example |
8 |
0 |
A |
Tab |
2.8 |
4.2 |
2.8 |
4 |
2.9 |
3.5 |
Comparative Example |
[0049] Furthermore, under the conditions 3 and 4 in which the die B provided with a gentle
transition part on the delivery side 3 is used, and conditions 5 and 6 in which the
die C provided with a gentle transition part on both of the entry side and delivery
side is used, the feed boundary is hardly recognizable by sight and the angular difference
between adjacent portions is about half of the variation of the edge bending angle
of the stationary portion. Meanwhile, under the conditions 1, 2, 7 and 8 in which
the die A is used, the feed boundary is clearly recognizable, and the angular difference
between adjacent portions is the same as the variation of the edge bending angle of
the stationary portion, and the edge bending angle sharply changes as compared with
the case where the die B or die C is used.
[0050] When comparing the conditions 1, 3 and 5, and conditions 2, 4 and 6, in which only
the die used is different, there are little differences in the variation of the edge
bending angle although the variation is smaller in some cases using the die C, and
it can be seen that a transition part may be formed at least on the delivery side
3.
[0051] Furthermore, under the conditions 1, 3, 5 and 7 in which the longitudinal end of
the steel plate is stopped to be positioned at the end of the flat part, the variation
of the edge bending angle of the stationary portion is the same as the variation of
the edge bending angle of the entire length, and the variation of the peaking of the
stationary portion is the same as the variation of the peaking of the entire length,
and the amount of edge bending is the same across the entire length. Meanwhile, under
the conditions 2, 4, 6 and 8 in which the longitudinal end of the steel plate is positioned
on the inner side of the flat part of the lower die, the amount of edge bending is
large at the end and the variation across the entire length is large. In particular,
under the condition 3 in which the "die B" is used and the longitudinal end of the
steel plate is stopped at the position of the end of the flat part, and the condition
5 in which "die C" is used and the longitudinal end of the steel plate is stopped
at the position of the end of the flat part, the variation of the peaking is 0.8 to
0.9 mm, which is not more than one seventh of ± 3.2 mm, a peaking tolerance required
by API standards, and it can be understood that the shape is superior.
[0052] Under the conditions 7 and 8 that do not satisfy the conditions of the present invention,
as compared with the inventive examples, the variations of the peaking and the edge
bending angle are larger. In particular, the large difference in edge bending angle
indicates that an abrupt change occurs at the step of the feed boundary. Since this
abrupt change exceeds the profiling limit of a welding torch, the welding is stopped
urgently.
EXAMPLE 3
[0053] A steel plate having a tensile strength of 500 MPa, a plate width of 3232 mm × a
plate thickness of 38.1 mm × a length of 12 m including a tab plate having a length
of 400 mm × a width of 100 mm attached to the leading end portion and the trailing
end portion is prepared, and a steel pipe having an outer diameter of 1067 mm is manufactured.
The upper die used for the edge bending has a processing face having a radius of curvature
of 400 mm. The edge bending is performed with a goal of providing an edge bending
angle of 22 degrees to a range of 195 mm at the widthwise edges of the steel plate.
The other edge bending conditions such as the edge bending apparatus, the lower die,
and the feed amount of the steel plate are the same as those of Example 1. The edge
bending angle is measured after the edge bending, and then the steel plate is formed
into a cylindrical shape by U-ing press and O-ing press, followed by welding to give
a steel pipe.
[0054] The edge bending conditions and the formation results are indicated in Table 3. The
items and descriptions in Table 3 are the same as those of Example 1. As shown in
Table 3, under conditions 1 to 6 (inventive examples) in which the center C1 of the
flat part of the lower die in the conveyance direction is set to be displaced 150
mm (displacement amount d) to the delivery side 3 in the conveyance direction relative
to the center C2 of the central hydraulic cylinder, the variation of the edge bending
angle and the variation of the peaking of the stationary portion are suppressed to
about half of those of conditions 7 and 8 (comparative examples) in which the center
C1 of the flat part of the lower die is set to match the center C2 of the central
hydraulic cylinder.
Table 3
Condition No. |
Displacement amount d [mm] |
Die |
Leading/trailing end stop position |
Variation in edge bending angle |
Angular difference between portions adjacent to each other [°] |
Number of stop of welding |
Variation in peaking of steel pipe |
Remarks |
Stationary portion [°] |
Entire length [°] |
Stationary portion [mm] |
Entire length [mm] |
1 |
150 |
A |
Steel plate |
0.9 |
0.9 |
0.9 |
0 |
1.0 |
1.0 |
Inventive Example |
2 |
150 |
A |
Tab |
0.8 |
1.1 |
0.8 |
0 |
0.9 |
1.3 |
Inventive Example |
3 |
150 |
B |
Steel plate |
0.8 |
0.8 |
0.5 |
0 |
0.8 |
0.8 |
Inventive Example |
4 |
150 |
B |
Tab |
1.0 |
1.4 |
0.4 |
0 |
0.9 |
1.5 |
Inventive Example |
5 |
150 |
C |
Steel plate |
0.7 |
0.7 |
0.4 |
0 |
0.7 |
0.7 |
Inventive Example |
6 |
150 |
C |
Tab |
0.9 |
1.2 |
0.4 |
0 |
0.8 |
1.3 |
Inventive Example |
7 |
0 |
A |
Steel plate |
2.3 |
2.3 |
2.3 |
3 |
2.5 |
2.5 |
Comparative Example |
8 |
0 |
A |
Tab |
2.6 |
3.9 |
2.6 |
4 |
2.7 |
3.2 |
Comparative Example |
[0055] Furthermore, under the conditions 3 and 4 in which the die B provided with a gentle
transition part on the delivery side 3 is used, and conditions 5 and 6 in which the
die C provided with a gentle transition part on both of the entry side and delivery
side is used, the feed boundary is visually hardly recognizable and the angular difference
between adjacent portions is about half of the variation of the edge bending angle
of the stationary portion. Meanwhile, under the conditions 1, 2, 7 and 8 in which
the die A is used, the feed boundary is clearly recognizable, and the angular difference
between adjacent portions is the same as the variation of the edge bending angle of
the stationary portion, and the edge bending angle sharply changes as compared with
the case where the die B or die C is used. When comparing the conditions 1, 3 and
5, and conditions 2, 4 and 6, in which only the die used is different, there are little
differences in the variation of the edge bending angle although the variation is smaller
in some cases using the die C, and it can be seen that a transition part may be formed
at least on the delivery side 3.
[0056] Furthermore, under the conditions 1, 3, 5 and 7 in which the longitudinal end of
the steel plate is stopped to be positioned at the end of the flat part, the variation
of the edge bending angle of the stationary portion is the same as the variation of
the edge bending angle of the entire length, and the variation of the peaking of the
stationary portion is the same as the variation of the peaking of the entire length,
and the amount of edge bending is the same across the entire length. Meanwhile, under
the conditions 2, 4, 6 and 8 in which the longitudinal end of the steel plate is positioned
on the inner side of the flat part of the lower die, the amount of edge bending is
large at the end and the variation across the entire length is large. In particular,
under the condition 3 in which the "die B" is used and the longitudinal end of the
steel plate is stopped at the position of the end of the flat part, and the condition
5 in which "die C" is used and the longitudinal end of the steel plate is stopped
at the position of the end of the flat part, the variation of the peaking is 0.7 to
0.8 mm, which is not more than one eighth of ± 3.2 mm, a peaking tolerance required
by API standards, and it can be understood that the shape is superior.
[0057] Under the condition Nos. 7 and 8 that do not satisfy the conditions of the present
invention, as compared with the inventive examples, the variations of the peaking
and the edge bending angle are large. In particular, the large difference in edge
bending angle indicates that an abrupt change occurs at the step of the feed boundary.
Since this abrupt change exceeds the profiling limit of a welding torch, the welding
is stopped urgently.
EXAMPLE 4
[0058] Similarly in Example 2, a steel plate having a tensile strength of 550 MPa, a plate
width of 2753 mm × a plate thickness of 38.1 mm × a length of 12 m including a tab
plate having a length of 400 mm × a width of 100 mm attached to the leading end portion
and the trailing end portion is prepared, and a steel pipe having an outer diameter
of 914 mm is manufactured. The upper die used for the edge bending has a processing
face having a radius of curvature of 335 mm, and the flat part of the lower die has
a processing face having a radius of curvature of 335 mm so as to match the upper
die. The edge bending is performed with a goal of providing an edge bending angle
of 24 degrees to a range of 180 mm at the widthwise edges of the steel plate by using
three types of lower dies: one in which the flat part has a length of 3000 mm and
both ends thereof in the longitudinal direction are chamfered at C25 mm (hereinafter
called the "die A"); another including a gentle transition part of R1200 mm formed
continuously from the flat part having a length of 3000 mm on the delivery side 3
in the conveyance direction (hereinafter called the "die B"); and the other including
a gentle transition part of R1200 mm formed continuously from the flat part having
a length of 3000 mm on both of the entry side 2 and the delivery side 3 (hereinafter
called the "die C").
[0059] The other edge bending conditions such as the edge bending apparatus and the feed
amount of the steel plate are the same as those of Example 2. The edge bending angle
is measured after the edge bending, and then the steel plate is formed into a cylindrical
shape by a bending press method, followed by welding to give a steel pipe. The edge
bending conditions and the formation results are indicated in Table 4. The items and
descriptions in Table 4 are the same as those of Example 1.
[0060] As indicated in Table 4, under conditions 1 to 6 (inventive examples) in which the
center C1 of the flat part 24a of the lower die in the conveyance direction 1 is set
to be displaced 150 mm (displacement amount d) to the delivery side 3 in the conveyance
direction 1 relative to the center of the central hydraulic cylinder, i.e., the center
C2 of the pressing force P, the variation of the edge bending angle and the variation
of the peaking of the stationary portion are suppressed to about half of those of
conditions 7 and 8 (comparative examples) in which the center C1 of the flat part
24a of the lower die is set to match the center C2 of the central hydraulic cylinder.
Table 4
Condition No. |
Displacement amount d [mm] |
Die |
Leading/trailing end stop position |
Variation in edge bending angle |
Angular difference between portions adjacent to each other [°] |
Number of stop of welding |
Variation of steel pipe |
Remarks |
Stationary portion [°] |
Entire length [°] |
Stationary portion [mm] |
Entire length [mm] |
1 |
150 |
A |
Steel plate |
1.0 |
1.0 |
0.9 |
0 |
0.9 |
0.9 |
Inventive Example |
2 |
150 |
A |
Tab |
0.7 |
1.0 |
0.8 |
0 |
0.9 |
1.3 |
Inventive Example |
3 |
150 |
B |
Steel plate |
0.9 |
0.8 |
0.4 |
0 |
0.8 |
0.9 |
Inventive Example |
4 |
150 |
B |
Tab |
1.0 |
1.5 |
0.4 |
0 |
0.9 |
1.6 |
Inventive Example |
5 |
150 |
C |
Steel plate |
0.7 |
0.8 |
0.4 |
0 |
0.7 |
0.8 |
Inventive Example |
6 |
150 |
C |
Tab |
0.8 |
1.2 |
0.4 |
0 |
0.8 |
1.2 |
Inventive Example |
7 |
0 |
A |
Steel plate |
2.5 |
2.1 |
2.2 |
3 |
2.6 |
2.6 |
Comparative Example |
8 |
0 |
A |
Tab |
2.4 |
3.9 |
2.8 |
4 |
2.4 |
3.4 |
Comparative Example |
[0061] Furthermore, under the conditions 3 and 4 in which the die B provided with a gentle
transition part on the delivery side 3 is used, and conditions 5 and 6 in which the
die C provided with a gentle transition part on both of the entry side and delivery
side is used, the feed boundary is visually hardly recognizable and the angular difference
between adjacent portions is about half of the variation of the edge bending angle
of the stationary portion. Meanwhile, under the conditions 1, 2, 7 and 8 in which
the die A is used, the feed boundary is clearly recognizable, and the angular difference
between adjacent portions is the same as the variation of the edge bending angle of
the stationary portion, and the edge bending angle sharply changes as compared with
the case where the die B or die C is used. When comparing the conditions 1, 3 and
5, and conditions 2, 4 and 6, in which only the die used is different, there are little
differences in the variation of the edge bending angle although the variation is smaller
in some cases using the die C, and it can be seen that a transition part may be formed
at least on the delivery side 3.
[0062] Furthermore, under the conditions 1, 3, 5 and 7 in which the longitudinal end of
the steel plate is stopped to be positioned at the end of the flat part, the variation
of the edge bending angle of the stationary portion is the same as the variation of
the edge bending angle of the entire length, and the variation of the peaking of the
stationary portion is the same as the variation of the peaking of the entire length,
and the amount of edge bending is the same across the entire length. Meanwhile, under
the conditions 2, 4, 6 and 8 in which the longitudinal end of the steel plate is positioned
on the inner side of the flat part of the lower die, the amount of edge bending is
large at the end and the variation across the entire length is large. In particular,
under the condition 3 in which the "die B" is used and the longitudinal end of the
steel plate is stopped at the position of the end of the flat part, and the condition
5 in which "die C" is used and the longitudinal end of the steel plate is stopped
at the position of the end of the flat part, the variation of the peaking is 0.8 to
0.9 mm, which is not more than one seventh of ± 3.2 mm, a peaking tolerance required
by API standards, and it can be understood that the shape is superior.
[0063] Under the condition Nos. 7 and 8 that do not satisfy the conditions of the present
invention, as compared with the inventive examples, the variations of the peaking
and the edge bending angle are large. In particular, the large difference in edge
bending angle indicates that an abrupt change occurs at the step of the feed boundary.
Since this abrupt change exceeds the profiling limit of a welding torch, the welding
is stopped urgently.
EXAMPLE 5
[0064] Similarly to Example 3, a steel plate having a tensile strength of 500 MPa, a plate
width of 3232 mm × a plate thickness of 38.1 mm × a length of 12 m including a tab
plate having a length of 400 mm × a width of 100 mm attached to the leading end portion
and the trailing end portion is prepared, and a steel pipe having an outer diameter
of 1067 mm is manufactured. The upper die used for the edge bending has a processing
face having a radius of curvature of 400 mm, and the flat part of the lower die has
a processing face having a radius of curvature of 400 mm so as to match the upper
die. The edge bending is performed with a goal of providing an edge bending angle
of 22 degrees to a range of 195 mm at the widthwise edges of the steel plate by using
three types of lower dies: one in which the flat part has a length of 3000 mm and
both ends thereof in the longitudinal direction are chamfered at C25 mm (hereinafter
called the "die A"); another including a gentle transition part of R1200 mm formed
continuously from the flat part having a length of 3000 mm on the delivery side 3
in the longitudinal direction (hereinafter called the "die B"); and the other including
a gentle transition part of R1200 mm formed continuously from the flat part having
a length of 3000 mm on both of the entry side 2 and the delivery side 3 (hereinafter
called the "die C").
[0065] The other edge bending conditions such as the edge bending apparatus and the feed
amount of the steel plate are the same as those of Example 3. The edge bending angle
is measured after the edge bending, and then the steel plate is formed into a cylindrical
shape by a bending press method, followed by welding to give a steel pipe. The edge
bending conditions and the formation results are indicated in Table 5. The items and
descriptions in Table 5 are the same as those of Example 1.
[0066] Under conditions 1 to 6 (inventive examples) in which the center C1 of the flat part
of the lower die in the conveyance direction is set to be displaced 150 mm (displacement
amount d) to the delivery side 3 in the conveyance direction relative to the center
C of the central hydraulic cylinder, i.e., the center C2 of the pressing force P,
the variation of the edge bending angle and the variation of the peaking of the stationary
portion are suppressed to about half of those of conditions 7 and 8 (comparative examples)
in which the center C1 of the flat part of the lower die is set to match the center
C2 of the central hydraulic cylinder.
Table 5
Condition No. |
Displacement amount d [mm] |
Die |
Leading/trailing end stop position |
Variation in edge bending angle |
Angular difference between portions adjacent to each other [°] |
Number of stop of welding |
Variation in peaking of steel pipe |
Remarks |
Stationary portion [°] |
Entire length [°] |
Stationary portion [mm] |
Entire length [mm] |
1 |
150 |
A |
Steel plate |
1.0 |
1.0 |
0.9 |
0 |
0.9 |
0.9 |
Inventive Example |
2 |
150 |
A |
Tab |
0.7 |
1.0 |
0.8 |
0 |
0.9 |
1.3 |
Inventive Example |
3 |
150 |
B |
Steel plate |
0.9 |
0.8 |
0.4 |
0 |
0.8 |
0.9 |
Inventive Example |
4 |
150 |
B |
Tab |
1.0 |
1.5 |
0.4 |
0 |
0.9 |
1.6 |
Inventive Example |
5 |
150 |
C |
Steel plate |
0.7 |
0.8 |
0.4 |
0 |
0.7 |
0.8 |
Inventive Example |
6 |
150 |
C |
Tab |
0.8 |
1.2 |
0.4 |
0 |
0.8 |
1.2 |
Inventive Example |
7 |
0 |
A |
Steel plate |
2.5 |
2.1 |
2.2 |
3 |
2.6 |
2.6 |
Comparative Example |
8 |
0 |
A |
Tab |
2.4 |
3.9 |
2.8 |
4 |
2.4 |
3.4 |
Comparative Example |
[0067] Furthermore, under the conditions 3 and 4 in which the die B provided with a gentle
transition part on the delivery side 3 is used, and conditions 5 and 6 in which the
die C provided with a gentle transition part on both of the entry side and delivery
side is used, the feed boundary is visually hardly recognizable and the angular difference
between adjacent portions is about half of the variation of the edge bending angle
of the stationary portion. Meanwhile, under the conditions 1, 2, 7 and 8 in which
the die A is used, the feed boundary is clearly recognizable, and the angular difference
between adjacent portions is the same as the variation of the edge bending angle of
the stationary portion, and the edge bending angle sharply changes as compared with
the case where the die B or die C is used. When comparing the conditions 1, 3 and
5, and conditions 2, 4 and 6, in which only the die used is different, there are little
differences in the variation of the edge bending angle although the variation is smaller
in some cases using the die C, and it can be seen that a transition part may be formed
at least on the delivery side 3.
[0068] Furthermore, under the conditions 1, 3, 5 and 7 in which the longitudinal end of
the steel plate is stopped to be positioned at the end of the flat part, the variation
of the edge bending angle of the stationary portion is the same as the variation of
the edge bending angle of the entire length, and the variation of the peaking of the
stationary portion is the same as the variation of the peaking of the entire length,
and the amount of edge bending is the same across the entire length. Meanwhile, under
the conditions 2, 4, 6 and 8 in which the longitudinal end of the steel plate is positioned
on the inner side of the flat part of the lower die, the amount of edge bending is
large at the end and the variation across the entire length is large. In particular,
under the condition 3 in which the "die B" is used and the longitudinal end of the
steel plate is stopped at the position of the end of the flat part, and the condition
5 in which "die C" is used and the longitudinal end of the steel plate is stopped
at the position of the end of the flat part, the variation of the peaking is 0.7 to
0.8 mm, which is not more than one eighth of ± 3.2 mm, a peaking tolerance required
by API standards, and it can be understood that the shape is superior.
[0069] Under the condition Nos. 7 and 8 that do not satisfy the conditions of the present
invention, as compared with the inventive examples, the variations of the peaking
and the edge bending angle are large. In particular, the large difference in edge
bending angle indicates that an abrupt change occurs at the step of the feed boundary.
Since this abrupt change exceeds the profiling limit of a welding torch, the welding
is stopped urgently.
Industrial Applicability
[0070] According to the present invention, it is possible to obtain an edge bending shape
with less variation across the entire length without introducing a new facility.
DESCRIPTION OF REFERENCE NUMERALS
[0071]
1 conveyance direction
2 entry side (upstream side in the conveyance direction)
3 delivery side (downstream side in the conveyance direction)
10 edge miller
20 edge bending apparatus of steel plate
21 conveyance mechanism
21a conveyance roll
22A, 22B press mechanism
23 upper die
24 lower die
24a flat part
24b, 24c transition part
26 hydraulic cylinder
30 cylinder-forming apparatus
30A U-ing press
30B O-ing press
30C bending press
40 joining apparatus
50 mechanical expander
S steel plate
Sa leading end portion
Sb trailing end portion
Sc, Sd widthwise edge
St tab plate
Sp product pipe shape
Se virtual perfect circle
Ra1 range of flat part 24a of lower die at the first bending
Ra2 range of flat part 24a of lower die at the second bending
Da angle variation at widthwise edge of steel plate
Dc angle variation in stationary portion
Df deformation force
P hydraulic pressure (pressing force)
Dp peaking
Dp- minus peaking
Dp+ plus peaking
1. An edge bending method of a steel plate using an edge bending apparatus of a steel
plate comprising:
a pair of dies configured to be arranged corresponding to a widthwise edge of a steel
plate;
an actuator configured to clamp the pair of dies with a predetermined pressing force;
and
a conveyance mechanism configured to convey the steel plate in a direction along a
longitudinal direction of the steel plate as a conveyance direction,
in which the widthwise edge of the steel plate is subjected to edge bending across
an entire length by performing edge bending of the widthwise edge of the steel plate
several times by the pair of dies while the steel plate is intermittently conveyed
by the conveyance mechanism,
characterized in that
one of the pair of dies that contacts a surface positioned at the outer side of edge
bending of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending, and edge bending is performed
on the widthwise edge of the steel plate with a center of the flat part in the conveyance
direction being displaced to a delivery side in the conveyance direction relative
to a center of the pressing force generated by the actuator in the conveyance direction.
2. The edge bending method of a steel plate according to claim 1,
wherein the die that contacts the surface positioned at the outer side of edge bending
comprises a transition part formed of a curved surface provided adjacent to the flat
part at least on a delivery side in the conveyance direction, and the flat part and
the transition part are connected to have a common tangent line.
3. The edge bending method of a steel plate according to claim 1 or 2,
wherein a leading end portion of the steel plate in the conveyance direction is at
a position corresponding to a front end of the flat part in a first pass of bending
the widthwise edge of the steel plate.
4. The edge bending method of a steel plate according to any one of claims 1 to 3,
wherein a trailing end portion of the steel plate in the conveyance direction is at
a position corresponding to a rear end of the flat part in a final pass for bending
the widthwise edge of the steel plate.
5. A method for manufacturing a steel pipe comprising:
an edge bending process of a steel plate using an edge bending apparatus of a steel
plate comprising
a pair of dies configured to be arranged corresponding to the widthwise edge of the
steel plate,
an actuator configured to clamp the pair of dies with a predetermined pressing force,
and a conveyance mechanism configured to convey the steel plate in a direction along
with a longitudinal direction of the steel plate as a conveyance direction,
in which the widthwise edge of the steel plate is subjected to edge bending across
an entire length by performing edge bending of the widthwise edge of the steel plate
several times by the pair of dies while the steel plate is intermittently conveyed
by the conveyance mechanism;
a cylinder-forming process in which the steel plate with the widthwise edges subjected
to edge bending is formed into a cylindrical shape and the widthwise edges of the
steel plate are butted with each other; and
a joining process in which the butted widthwise edges of the steel plate are welded,
characterized in that
one of the pair of dies that contacts a surface positioned at the outer side of edge
bending of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending,
and edge bending is performed on the widthwise edge of the steel plate with a center
of the flat part in the conveyance direction being displaced to a delivery side in
the conveyance direction relative to a center of the pressing force generated by the
actuator in the conveyance direction.
6. An edge bending apparatus of a steel plate comprising:
a pair of dies configured to be arranged corresponding to widthwise edge of a steel
plate;
an actuator configured to clamp the pair of dies with a predetermined pressing force;
and
a conveyance mechanism configured to convey the steel plate in a direction along a
longitudinal direction of the steel plate as a conveyance direction,
in which the widthwise edge of the steel plate is subjected to edge bending across
an entire length by performing edge bending of the widthwise edge of the steel plate
several times by the pair of dies while the steel plate is intermittently conveyed
by the conveyance mechanism,
characterized in that
one of the pair of dies that contacts a surface positioned at the outer side of edge
bending of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending,
and a center of the flat part in the conveyance direction is displaced to a delivery
side in the conveyance direction relative to a center of the pressing force generated
by the actuator in the conveyance direction.
7. The edge bending apparatus of a steel plate according to claim 6, wherein the die
that contacts the surface positioned at the outer side of edge bending comprises a
transition part formed of a curved surface provided adjacent to the flat part at least
on a delivery side in the conveyance direction, and the flat part and the transition
part are connected to have a common tangent line.
8. A facility for manufacturing a steel pipe comprising:
an edge bending apparatus of a steel plate comprising
a pair of dies configured to be arranged corresponding to widthwise edge of a steel
plate,
an actuator configured to clamp the pair of dies with a predetermined pressing force,
and
a conveyance mechanism configured to convey the steel plate in a direction along a
longitudinal direction of the steel plate as a conveyance direction, in which the
widthwise edge of the steel plate is subjected to edge bending across an entire length
by performing edge bending of the widthwise edge of the steel plate several times
by the pair of dies while the steel plate is intermittently conveyed by the conveyance
mechanism;
a cylinder-forming apparatus configured to form the steel plate with the widthwise
edges subjected to edge bending into a cylindrical shape and butt the widthwise edges
of the steel plate with each other; and
a joining apparatus configured to weld the butted widthwise edges of the steel plate,
characterized in that
one of the pair of dies that contacts a surface positioned at the outer side of edge
bending of the widthwise edge of the steel plate to be bent has a flat part that contacts
the surface positioned at the outer side of edge bending, and
a center of the flat part in the conveyance direction is displaced to a delivery side
in the conveyance direction relative to a center of the pressing force generated by
the actuator in the conveyance direction.
9. The facility for manufacturing a steel pipe according to claim 8,
wherein the die that contacts the surface positioned at the outer side of edge bending
comprises a transition part formed of a curved surface provided adjacent to the flat
part at least on a delivery side in the conveyance direction, and the flat part and
the transition part are connected to have a common tangent line.