JP5849895B2 - Drawing rolling device and roll for drawing rolling device - Google Patents

Description

  The present invention relates to a drawing apparatus, and more particularly to a drawing apparatus for drawing a metal tube and a roll for the drawing apparatus.

  2. Description of the Related Art A drawing apparatus represented by a sizer or a stretch reducer draws a metal tube to a predetermined outer dimension. Known types of drawing mills include a three-roll type drawing rolling device having a plurality of stands each having three rolls, a four-roll type drawing rolling device in which each stand has four rolls, and the like. .

  A drawing mill usually includes a plurality of stands arranged along a pass line. Each stand includes a plurality of rolls having grooves that form a hole mold. For example, in a three-roll type drawing rolling apparatus, three rolls are arranged at equal intervals around the pass line, and are shifted by 60 ° around the rolling axis from the three rolls included in the preceding stage stand. This is to make the distribution of the radial stress acting on the outer periphery of the pipe during the drawing rolling as uniform as possible.

  Each stand of the four-roll type drawing mill includes four rolls having grooves that form a hole mold. The four rolls are arranged at equal intervals around the rolling axis, and are shifted by 45 ° around the rolling axis from the four rolls of the preceding stage stand.

  Such a regular arrangement of rolls may cause uneven thickness in the metal tube. Specifically, the transverse shape of the inner peripheral surface of the metal tube after drawing rolling may be a polygon such as a hexagon or an octagon instead of a circle. Such uneven thickness of the metal tube is referred to as “inner surface angularity”.

  Japanese Patent Laid-Open No. 6-238308 (Patent Document 1) proposes a drawing rolling method that suppresses internal angularity. In patent document 1, the radius of the flange side roll surface of each roll which comprises each roll stand of a drawing mill is made larger than the radius of the caliber bottom side roll surface. And let the cross shape of the caliber side roll surface be the circular arc which has a radius centering on the point offset outward from the rolling pass axis.

  International Publication No. 2005/070574 (Patent Document 2) proposes a drawing rolling apparatus that suppresses internal surface angularity and edge wrinkles. In patent document 2, in the groove | channel of the roll of each stand of a drawing rolling apparatus, the bottom part of a groove | channel is a circular arc which has a 1st radius centering on a rolling axis | shaft with a transverse shape, and the surface of the roll flange part of a groove | channel and rolling The distance between the axes is longer than the first radius. The distance between the edge of the groove and the rolling axis is longer than the first radius in the groove of the roll included in the preceding stage stand. In Patent Document 2, it is described that inner surface angularity is suppressed by making the bottom of the groove an arc having a first radius.

  Japanese Laid-Open Patent Publication No. 6-210318 (Patent Document 3) proposes a drawing rolling method that suppresses internal surface angularity. In Patent Document 3, in a four-roll type drawing rolling apparatus that performs cold rolling, the hole radius of the roll groove edge is larger than the hole radius of the roll groove center, and the hole in the center of the previous roll groove Smaller than the mold radius.

JP-A-6-238308 International Publication No. 2005/070574 Japanese Patent Laid-Open No. 6-210318

  However, even if the drawing rolling methods of Patent Documents 1 to 3 are used, inner surface angularity may occur.

  The objective of this invention is providing the drawing rolling apparatus which suppresses generation | occurrence | production of internal surface angularity.

  The drawing apparatus according to the present embodiment includes a plurality of stands arranged along a pass line, and draws a metal tube. The plurality of stands includes a plurality of rough stands and one or more finishing stands. The finishing stand is disposed behind the plurality of coarse stands. The coarse stand includes n (n ≧ 3) rolls arranged around the pass line. The n rolls are arranged 180 degrees / n around the pass line from the n rolls included in the preceding coarse stand. The roll has a groove having an arcuate transverse shape. The groove includes a bottom portion and a pair of flange portions. The flange portion is located between the bottom portion and the edge of the groove. The transverse shape of the bottom is an arc having a radius R0 shorter than the distance DB between the pass line and the center of the bottom. The distance DE between the groove edge and the pass line is longer than the distance DB.

  The drawing rolling apparatus according to the present embodiment suppresses the occurrence of internal surface angularity.

FIG. 1 is a side view of a drawing apparatus according to the present embodiment. FIG. 2 is a front view of the rough stand in FIG. FIG. 3 is a front view of a coarse stand in front of the coarse stand of FIG. FIG. 4 is a schematic diagram showing the drawing rolling of a metal tube by the drawing rolling apparatus shown in FIG. FIG. 5 is a front view of the roll in the rough stand in FIGS. 2 and 3. FIG. 6 is a cross-sectional view of a metal tube with internal angulation. FIG. 7 is a front view of a roll having a single R groove. FIG. 8 is a front view of a roll having a double R groove. FIG. 9 is a schematic diagram for explaining the shape of the groove shown in FIG. FIG. 10 is a cross-sectional view of the outer peripheral surface of a metal tube rolled with a roll having a single R groove shown in FIG. FIG. 11 is a diagram showing a positional relationship between the metal tube and the single R roll groove immediately before rolling of the metal tube shown in FIG. 12 is an FEM analysis result diagram showing a stress distribution in the circumferential direction applied to the metal tube rolled in FIG. FIG. 13 is a cross-sectional view of the outer peripheral surface of a metal tube rolled with a roll having grooves shown in FIG. 14 is a diagram showing the positional relationship between the metal tube and the groove shown in FIG. 5 immediately before rolling the metal tube in FIG. FIG. 15 is a FEM analysis result diagram showing a stress distribution in the circumferential direction applied to the metal tube rolled in FIG. FIG. 16 is an FEM analysis result diagram showing the variation in the thickness of the metal tube drawn and rolled in the example.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Configuration of Drawing Roller]
FIG. 1 is a side view of a drawing apparatus 1 according to the present embodiment. With reference to FIG. 1, the drawing apparatus 1 includes a plurality of stands ST arranged along a pass line PL. The plurality of stands ST includes a plurality of coarse stands ST1 to STm (m is a natural number) and finishing stands STm + 1 to STk (k is a natural number larger than m).

  The coarse stands ST1 to STm mainly reduce the diameter of the metal tube. The finishing stands STm + 1 to STk are arranged in a line behind the coarse stands ST1 to STm. The finishing stands STm + 1 to STk adjust the shape of the metal tube reduced in diameter by the coarse stands ST1 to STm, and increase the roundness of the transverse shape of the outer peripheral surface of the metal tube. In general, the finishing stand refers to a stand whose rolling reduction is set to 3% or less among a plurality of stands arranged on the rear side including the final stand of the drawing mill 1. Here, the rolling reduction in the i-th stand STi is expressed as (average diameter of the hole type of the stand STi-1−average diameter of the hole type of the stand STi) / average diameter of the hole type of the stand STi-1 × 100%. Is done. However, the average diameter of the hole type is the distance between the pass line PL and the roll groove bottom center (distance DB in FIG. 5) and the distance between the pass line PL and the roll groove edge (distance DE in FIG. 5). It is sum.

  In FIG. 1, a plurality of finishing stands STm + 1 to STk are provided behind the plurality of rough stands ST1 to STm. However, the drawing apparatus 1 may include only one finishing stand STm + 1 behind the plurality of rough stands ST1 to STm. However, for example, when each stand is constituted by three rolls, the rolling directions of the three rolls are different in adjacent stands as shown in FIGS. 2 and 3 described later. In such a case, it is desirable to provide at least one finishing stand for each reduction direction. Therefore, in the case of a drawing rolling apparatus of a type in which each stand has three rolls, it is desirable to have at least two finishing stands.

  2 and 3 are front views of the coarse stand STi (i = 2 to m) and the stand STi-1. The stand STi-1 is arranged in front of the stand STi. With reference to FIGS. 2 and 3, each coarse stand ST includes three rolls 10. It includes three rolls 10 arranged at 120 ° positions around the pass line PL. The roll 10 has a groove 20 having an arcuate cross section, and the grooves 20 of the three rolls RO form a hole type PA.

  As shown in FIGS. 2 and 3, three (n = 3) rolls 10 included in the coarse stand STi are 60 ° around the pass line PL from the three rolls 10 included in the preceding stage STi−1. = 180 ° / n, n = 3) are shifted.

  The three rolls 10 of each stand ST are connected to each other by a bevel gear (not shown), and one of the three rolls 10 is rotated by a motor (not shown). Thereby, all the rolls 10 rotate. Three rolls 10 may be rotated by three motors.

  The cross-sectional area of the hole type formed by the three rolls of each stand ST is smaller as that of the subsequent stage ST. In other words, the cross-sectional area of the hole mold formed by the stand ST1 is the largest, and the cross-sectional area of the hole mold formed by the last stand STk is the smallest. As shown in FIG. 4, the metal tube HS is drawn and rolled along the pass line PL from the stand ST1 to the stand STk.

[Roll stand ST1 to STm roll 10]
The roll 10 included in the coarse stands ST1 to STm has a groove 20 shown in FIG. Hereinafter, in the present specification, the shape of the groove 20 in a cross section including the roll axis of the roll 10 is referred to as a “transverse shape” of the groove 20. The transverse shape of the groove 20 is arcuate.

  The groove 20 includes a bottom portion 21 and a pair of flange portions 22. The bottom portion 21 is disposed at the center of the groove 20. The transverse shape of the bottom 21 is an arc having a point C21 as a center (hereinafter, point C21 is referred to as a center C21) and a radius R0. The center C21 is disposed closer to the groove 20 than the pass line PL. More specifically, the center C <b> 21 is disposed between the pass line PL and the center GB of the bottom portion 21. Therefore, the radius R0 is shorter than the distance DB between the pass line PL and the bottom center GB. Since the radius R0 is shorter than the distance DB, the curvature of the transverse shape of the bottom 21 is larger than the curvature of the arc centered on the pass line PL. Thereby, it is possible to suppress the occurrence of internal angularity in the metal tube.

  The flange portion 22 is disposed between the end 23 of the bottom portion 21 and the edge GE of the groove 20. The distance DE between the pass line PL and the groove edge GE is longer than the distance DB. In FIG. 5, the transverse shape of the flange portion 22 is an arc having a radius R1. The radius R1 is longer than the radius R0. Since the distance DB is longer than the distance DE and the radius R1 is longer than the radius R0, the occurrence of edge flaws during rolling is suppressed.

  FIG. 6 is a cross-sectional view of a metal tube in which internal surface angularity has occurred after rolling by a three-roll type drawing mill. With reference to FIG. 6, in this specification, an axis extending right above the center CN of the metal tube HS is defined as a reference axis REF. A point on the reference axis REF in the outer peripheral surface of the metal pipe HS is referred to as a point “P0”. Further, on the outer peripheral surface of the metal pipe HS, a point on a line segment that forms 30 ° with the reference axis REF is referred to as a point “P30”, and a point on the line segment that forms 60 ° with the reference axis REF is a point “P60”. Called.

  In the metal tube HS in which the inner surface is angulated, uneven thickness occurs and the inner surface has a polygonal shape. More specifically, in the cross section of the metal tube HS, a thin portion (hereinafter referred to as a thin portion) TA and a thick portion (hereinafter referred to as a thick portion) TB are around the central axis CN. Are alternately formed. The thick part TB is formed with a 30 ° shift around the central axis CN with respect to the thin part TA. And the thick part TB is arrange | positioned by 60 degree deviation | shift around the central axis CN with respect to other adjacent thick part TB. Similarly, the thin portion TA is also shifted by 60 ° around the central axis CN with respect to other adjacent thin portions TA.

  The thin portion TA is formed at the points P0 and P60. That is, it is formed every 60 ° from the point P0. Similarly, the thick part TB is formed at the point P30, and is formed at intervals of 60 ° from the point P30. In short, in the metal tube HS in which the inner surface is angulated, the inner surface has a hexagonal cross-sectional shape.

  The thick-walled portion TB is likely to occur when the amount of rolling applied to the point P30 and the point every 60 ° from the point P30 (hereinafter simply referred to as the point P30) increases during the drawing rolling. This is because as the cumulative reduction amount during drawing rolling increases, the thickness increases due to reduction. Therefore, in order to reduce the thickness of the thick part T30 and suppress the inner surface angularity, the cumulative reduction amount at the point P30 may be reduced.

[Operation of groove 20]
Hereinafter, the operation of the roll 10 having the groove 20 will be described. The effect of the groove 20 will be described in comparison with a single R groove and a double R groove.

[Single R groove and Double R groove]
[Single R groove]
First, the single R groove and the double R groove will be described. FIG. 7 is a front view of a roll having a single R groove 50. Referring to FIG. 7, the transverse shape of the single R groove 50 is a single arc having a radius R50. The center C50 of the arc is arranged on an extension line on the pass line PL side of the line segment (reference axis REF) connecting the bottom center GB and the pass line PL. Therefore, the radius R50 is longer than the distance DB from the pass line PL to the bottom center GB.

  FIG. 7 shows a virtual circle VC having a radius DB and centering on the pass line PL. In the single R groove 50, a point at 30 ° from the reference axis REF around the pass line PL is defined as a “point G30”. The point G30 is disposed outside the virtual circle VC. Therefore, the distance D30 between the point G30 and the pass line PL is longer than the distance DB.

  Further, the distance DE between the groove edge GE and the pass line PL is longer than the distance D30. In short, the distance between an arbitrary point G of the single R groove 50 and the pass line PL becomes longer from the bottom center GB toward the groove edge GE.

[Double R groove]
FIG. 8 is a front view of a roll having a double R groove 60. Referring to FIG. 8, the transverse shape of double R groove 60 is arcuate, and has a bottom portion 601 and a pair of flange portions 602. The transverse shape of the bottom 601 is an arc having a radius R60 and a center C60. The center C60 is disposed on an extension line on the pass line PL side of a line segment (reference axis REF) connecting the bottom center GB and the pass line PL. Therefore, the radius R60 is longer than the distance DB, like the radius R50. The flange portion 602 is disposed between the end point 63 of the bottom portion 601 and the groove edge GE. The transverse shape of the flange portion 602 is an arc. The arc radius R61 of the flange portion 602 is larger than the arc radius R60 of the bottom portion 601. The center C61 of the arc of the flange portion 602 is disposed on an extension line on the center C60 side of a line segment connecting the end point 63 and the center C60. In short, the groove 60 includes two types of arcs.

  FIG. 8 also shows a virtual circle VC having a radius DB. The point G30 of the double R groove 60 is located outside the virtual circle VC. Therefore, the distance D30 between the point G30 and the pass line PL is larger than the distance DB. Further, the distance DE between the groove edge GE and the pass line PL is larger than the distance D30.

  From the above, the distance between an arbitrary point G on the double R groove 60 and the pass line PL becomes longer from the bottom center GB toward the groove edge GE, as in the single R groove 50.

[Shape of groove 20]
On the other hand, as shown in FIG. 9, the point G30 in the groove 20 of this embodiment is located inside the virtual circle VC. Therefore, the distance D30 between the point G30 and the pass line PL is shorter than the distance DB. Further, the distance DE is longer than the distance DB.

  In short, the distance between an arbitrary point G on the groove 20 and the pass line PL gradually decreases from the bottom center GB toward the periphery of the point G30 and increases again from the periphery of the point 30 toward the groove edge GE.

  As described above, in the single R groove 50 and the double R groove 60, the distance from the pass line PL gradually increases from the bottom center GB toward the groove edge GE. On the other hand, in the groove 20, the distance from the pass line PL once decreases from the bottom center GB toward the groove edge GE and increases again. Such a difference in the crossing shape of the grooves affects the shape of the outer peripheral surface of the metal tube HS after rolling at each rough stand ST. Hereinafter, this point will be described in detail.

[Metal tube shape after rolling with single R groove 50 and double R groove 60]
FIG. 10 is a cross-sectional view of the outer peripheral surface of the metal tube HS after being rolled in the stand STi-1 of the drawing apparatus having a single R groove 50. As described above, the distance between the single R groove 50 and the pass line PL increases from the bottom center GB toward the groove edge GE. Therefore, the transverse shape of the outer peripheral surface of the metal tube HS is a triangular shape having three top PTs every 120 ° from the reference axis REF, and each side being curved outwardly with respect to the pass line PL.

  The distance between the top PT and the pass line PL (hereinafter referred to as the outer radius R) is substantially equal to the distance DE. The outer radius R of the metal pipe HS gradually decreases from the pass line PL toward the point P60 shifted by 60 ° around the pass line PL from the top PT, and becomes the distance DB at the point P60. Then, the outer radius R of the metal pipe HS increases again from the point P60 toward the next top PT (position 120 ° from the point P0).

  FIG. 11 shows a single R groove 50 of the roll of the stand STi and the metal tube HS immediately before the metal tube HS rolled in the stand STi-1 (the metal tube in FIG. 10) is rolled into the subsequent stand STi. It is a figure which shows the positional relationship with the outer peripheral surface.

  Referring to FIG. 11, the roll of stand STi is arranged with a 60 ° shift around pass line PL as compared with the roll of stand STi-1. Therefore, at the time of rolling, the point P0 (top PT) of the metal pipe HS is arranged on the reference axis REF in the single R groove 50, like the bottom center GB. On the other hand, the point P60 of the metal pipe HS is disposed in the vicinity of the groove edge GE in the single R groove 50.

  In short, when rolling the metal pipe HS with the single R groove 50, the top PT that is rolled in the vicinity of the groove edge GE of the roll of the preceding stage STi-1 among the metal pipe HS and has the longest distance from the pass line PL is obtained. Of the single R groove 50 of the stand STi in the rear stage, it is arranged on the reference axis REF including the bottom center GB having the shortest distance from the pass line PL. The point P60 that is rolled at the bottom center GB of the roll of the stand STi-1 of the preceding stage in the metal tube HS and has the shortest distance from the pass line is the pass line PL of the single R groove 50 of the stand STi of the subsequent stage. Is disposed in the vicinity of the groove edge GE.

  FIG. 12 is a diagram showing a circumferential stress distribution applied to the metal pipe HS when the metal pipe HS is rolled with the single R groove 50 shown in FIG. 11. FIG. 12 was obtained by a finite element method (FEM) analysis. The figure corresponds to a metal pipe HS portion (that is, a range including points P0, P30, and P60) in a range of 60 ° around the pass line PL from the reference axis REF.

  Referring to FIG. 12, in the region TE of the metal pipe HS, tensile stress is applied in the circumferential direction. In the region COL, a low compressive stress is applied in the circumferential direction. In the region COH, a high compressive stress (about 2.5 times the low compressive stress) is applied in the circumferential direction.

  Referring to FIGS. 11 and 12, a portion corresponding to peripheral portion 200 including top PT in FIG. 11 is subjected to high compressive stress. And the high compressive stress is applied also in the point P30. This is presumably because the peripheral portion 200 overlaps with the roll as shown in FIG. 11, and thus the peripheral portion 200 is greatly reduced. On the other hand, high compressive stress is not applied to the portion around the point P60 of the metal pipe HS. As shown in FIG. 11, this is considered to be due to the fact that the periphery of the point P60 is not easily reduced by the roll.

  The description in FIGS. 10 to 12 is summarized as follows. As shown in FIG. 10, the metal tube HS after rolling in each rough stand ST has a substantially triangular shape. Then, the peripheral portion 200 of the top PT of the metal tube HS after rolling on the coarse stand STi-1 comes into contact with the bottom center GB of the coarse stand STi in the subsequent stage and is given a high compressive stress in the circumferential direction. On the other hand, in the vicinity of the point P60 of the metal pipe HS, it is difficult for the roll to be reduced by the roll in the vicinity of the groove edge GE of the single R groove 50 of the rough stand STi. Therefore, the peripheral part of the point P60 is not subjected to high compressive stress.

  After rolling on the stand STi, the point P60 of the metal pipe HS becomes the top PT. That is, the portion (P60) where the high compressive stress is not applied to the stand STi becomes the top PT of the metal tube HS. And the point P60 of the metal pipe HS is crushed in the stand STi + 1 and receives a high compressive stress in the circumferential direction. In short, the point P0 and the point P60 of the metal pipe HS are subjected to high circumferential compressive stress every other stand.

  On the other hand, the point P30 of the metal pipe HS receives a high circumferential compressive stress regardless of whether the top of the metal pipe HS is P0 or P60 with reference to FIG. . That is, at the point P30 of the metal pipe HS, a high circumferential compressive stress is easily applied to all the stands ST1 to STm.

  Therefore, when the rolling is performed with a groove whose distance from the pass line PL increases from the bottom center GB of the groove toward the groove edge GE like the single R groove 50, the portion around the point P30 of the metal pipe HS is Each coarse stand ST receives a high compressive stress in the circumferential direction. High compressive stress in the circumferential direction increases the thickness of the metal tube HS. Therefore, as shown in FIG. 6, the thick-walled portion TB is formed at the point P30 of the metal tube HS after the draw rolling (and the points every 60 ° from the point P30), and the inner surface is angulated.

  Similarly to the single R-groove 50, the double R-groove 60 also increases in distance from the pass line PL from the bottom center GB of the groove toward the groove edge GE. Accordingly, as in the case of the single R groove 50, the inner surface is easily angulated in the metal tube HS after the drawing.

[Metal tube shape after rolling by groove 20]
On the other hand, when the roll 10 having the groove 20 is used for drawing rolling, the circumferential compressive stress applied to the point P30 of the metal pipe HS is reduced. Hereinafter, this point will be described.

  FIG. 13 shows the shape of the metal tube HS rolled by the coarse stand STi-1 provided with the roll 10. As described with reference to FIG. 9, the distance between an arbitrary point G of the groove 20 and the pass line PL gradually decreases from the bottom center GB toward the vicinity of the point G30, and from the vicinity of the point G30 to the groove edge GE. It gets bigger again.

  Therefore, the transverse shape of the outer peripheral surface of the metal pipe HS after rolling has a hexagonal shape that has a top at every 60 ° geometrically from the reference axis REF, and each side is convexly curved on the opposite side to the pass line PL. Become a shape. The top is formed at the point P0 and the point P60 in the transverse shape of the metal tube HS.

  FIG. 14 shows the positional relationship between the metal tube HS immediately before rolling and the groove 20 of the coarse stand STi when such a metal tube HS is rolled by the subsequent coarse stand STi.

  Referring to FIG. 14, a point P0 corresponding to the top of the metal pipe HS is arranged on the reference axis REF similarly to the groove center GB of the groove 20, and a point P60 corresponding to the other top of the metal pipe HS is adjacent to the point P0. Arranged between the groove edges GE of the matching grooves 20.

  FIG. 15 is a stress distribution diagram in the circumferential direction applied to the metal pipe HS when rolled by the stand STi shown in FIG. FIG. 15 was obtained by the finite element method in the same manner as in FIG.

  Referring to FIG. 15, the high compressive stress is not applied to the peripheral portion of the point P30 as in the case of FIG. 12. As shown in FIG. 14, the overlapping portion with the roll 10 is larger in the peripheral portion of the point P0 than in the other portions. In this case, the peripheral part of the point P0 of the metal tube HS is first brought into contact with the groove 20 and rolled down during rolling. Due to the influence of the reduction, the diameter of the peripheral portion of the point P30 is reduced before contacting the groove 20. Therefore, it is considered that the portion around the point P30 is less likely to be reduced than the other outer peripheral portion, and it is difficult to apply a large compressive stress.

  As described above, in the drawing rolling in the groove 20, it is possible to suppress an excessive compressive stress from being applied to the point P30 of the metal pipe HS in each rough stand ST. Therefore, thickening is difficult to occur at the point P30, and the occurrence of inner surface angulation is suppressed.

  Returning to FIG. 5, in the groove 20, the center angle A0 of the arc of the bottom 21 is preferably about 60 °. This is because if the center angle A0 is too large, a new thickened portion may be formed at a location different from P30 of the metal tube HS. A preferable lower limit of the central angle A0 is 5 °, and more preferably 10 °. A preferable upper limit of the central angle A0 is 70 °.

  Preferably, the distance (hereinafter referred to as offset amount) OF between the pass line PL and the center C21 of the arc of the bottom portion 21 is 0.5% to 10% of the distance DB.

  In FIG. 5, the transverse shape of the flange portion 22 is an arc. However, the transverse shape of the flange portion 22 is not limited to an arc. For example, the flange portion 22 may be a straight line. When the flange portion 22 is a straight line, the tangent line 25 of the end 23 of the bottom portion 21 is preferable. In this case, the bottom part 21 and the flange part 22 are continuously and smoothly formed. When the flange portion 22 is arcuate, the flange portion 22 is preferably disposed on the pass line PL side with respect to the tangent line 25.

  Further, the flange portion 22 may include a plurality of arcs. In other words, the flange portion 22 may have a plurality of curvatures. For example, the transverse shape of the flange portion 22 is in contact with the end 23 of the bottom portion 21 and has a first arc having a radius R1 larger than the radius R0 and a radius R2 in contact with the end of the first arc and larger than the radius R1. The second arc may be included. The curved shape is not particularly limited as long as the flange portion has an arcuate shape and is smoothly connected to the bottom portion.

  The shape of the flange portion 22 is not particularly limited as long as the distance DE between the groove edge GE of the flange portion 22 and the pass line PL is larger than the distance DB between the bottom center GB and the pass line PL.

  In addition, the groove | channel of the roll contained in the final finishing stand ST among several stands ST of the drawing rolling apparatus 1 forms a perfect circular hole shape, for example. In this case, the hole type formed by the three grooves is an arc centered on the pass line PL. There may be one finishing stand ST or a plurality of finishing stands ST. When a plurality of finishing stands ST are arranged, the shape of the roll groove of other stands other than the final stand ST may be the groove 20 or other shapes.

  The roll having a groove according to the present embodiment described above can be applied to a drawing rolling device in which each stand includes more than three rolls, for example, a four roll type drawing rolling device. Even when a groove having the same shape as the groove 20 is formed on a four-roll roll, the inner surface angulation can be suppressed by the above-described action.

  FEM analysis of drawing rolling was performed using a drawing rolling device including rolls having various grooves, and the thickness of the metal tube after drawing rolling was determined.

[Test method]
A three-roll drawing mill with marks 1 to 4 was assumed. Each mark was provided with six rough stands ST1 to ST6 and finishing stands ST7 to ST9. Table 1 shows the roll groove dimensions of each type of coarse stand.

  With reference to Table 1, the groove | channel of each coarse stand ST1-ST6 of the mark 1 was the same shape as the groove | channel 20 shown in FIG. The groove of each coarse stand ST of the mark 2 has the same shape as the single R groove 50 shown in FIG. In the “R0” column of the mark 2 in Table 1, the value of the radius R50 in FIG. 7 is described. The groove of each coarse stand ST of the mark 3 has the same shape as the double R groove 60 shown in FIG. In the “R0” column of the mark 3 in Table 1, the value of the radius R60 in FIG. 8 is described. In the “R1” column, the value of the radius R61 in FIG. 8 is described. In the “A0” column, The value of the central angle of the bottom 601 is described. The roll groove of each coarse stand ST of the mark 4 in FIG. 5 is a groove in which the offset amount OF is “0”, that is, the center C21 of the arc of the bottom portion 21 coincides with the pass line PL. The groove was the same as the groove 20.

  As shown in Table 1, the reduction ratio (%) of each stand defined by the following formulas (1) to (3) was 1.5% for the first stage stand and 4% for the other coarse stands ST. It was.

Reduction ratio (%) = (average diameter D of coarse stand STi-1−average diameter D of coarse stand STi) / (average diameter D of coarse stand STi-1) × 100 (1)
However, average diameter D = DB + DE (2)
For the first stage stand,
Reduction ratio (%) = (Outer diameter of raw pipe−Average diameter D of first stage stand) / (Outer diameter of raw pipe) × 100 (3)

  The groove of each mark finishing stand ST7 and ST8 was a single R groove 50. The hole shape of the final finishing stand ST9 of each mark was a perfect circle (circle having a radius of 22.92 mm).

  The FEM analysis uses a 1/6 analysis model (range from the reference axis REF to 60 ° around the center CN) of the metal pipe HS corresponding to carbon steel with an outer diameter of 60 mm and a wall thickness of 6 mm. Was divided into a plurality of hexahedral elements.

  The thickness of the metal tube HS after drawing by FEM analysis was determined. Specifically, the thickness (mm) was obtained at intervals of about 3 ° around the central axis CN from the reference axis REF.

Based on the obtained thickness, the uneven thickness ratio (%) of each mark was obtained by the following equation (4).
Uneven thickness rate = (maximum thickness-minimum thickness) / average thickness x 100 (4)

[Test results]
FIG. 16 shows the thickness (mm) of the metal tube after drawing rolling at each mark at points about every 3 ° from the reference axis REF (deployment angle = 0 °). And Table 2 shows the thickness deviation rate (%) of the metal tube after the drawing rolling of each mark.

  With reference to FIG. 16 and Table 2, the mark 1 used the drawing rolling apparatus which has the groove | channel 20. FIG. Therefore, the uneven thickness of the metal tube was small and was less than 6%.

  On the other hand, the metal pipes marked 2 to 4 varied in thickness. And all the thickness deviation ratios exceeded 6%.

  While the embodiments of the present invention have been described above, the above-described embodiments are merely examples for carrying out the present invention. Therefore, the present invention is not limited to the above-described embodiment, and can be implemented by appropriately modifying the above-described embodiment without departing from the spirit thereof.

1 Drawing Roller 10 Roll 20 Groove 21 Bottom 22 Flange

Claims (3)

A drawing apparatus comprising a plurality of stands arranged along a pass line, and drawing and rolling a metal tube,
The plurality of stands are:
Multiple coarse stands,
One or more finishing stands arranged behind a plurality of rough stands,
The coarse stand includes n (n ≧ 3) rolls arranged around the pass line,
The n rolls are arranged 180 degrees / n around the pass line from the n rolls included in the coarse stand in the previous stage,
The roll has a groove having an arcuate transverse shape,
The groove includes a bottom portion and a pair of flange portions located between the bottom portion and an edge of the groove,
The bottom transverse shape is an arc having a radius R0 shorter than a distance DB between the pass line and the center of the bottom,
The distance DE between the edge of the groove the pass line, rather long than the distance DB,
The transverse shape of the flange part is an arcuate shape, the flange part and the bottom part are arranged on the pass line side with respect to the tangent of the end of the bottom part, and the flange part is smoothly connected to the bottom part . The drawing rolling apparatus according to claim 1 ,
The transverse rolling shape of the flange portion includes one or more arcs having a radius larger than the radius R0. A roll for a drawing rolling device used in a drawing rolling device comprising a plurality of rough stands arranged along a pass line, and drawing a metal tube along the pass line,
The roll has a groove having an arcuate transverse shape,
The groove includes a bottom portion and a pair of flange portions located between the bottom portion and an edge of the groove,
The bottom transverse shape is an arc having a radius R0 shorter than a distance DB between the pass line and the center of the bottom,
The distance DE between the edge of the groove the pass line, rather long than the distance DB,
A transverse shape of the flange portion is an arcuate shape, the flange portion and the bottom portion are arranged on the pass line side with respect to a tangent of the end of the bottom portion, and the flange portion is smoothly connected to the bottom portion . roll.

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