EP2524740A1 - Procédé de formation de presse de composant en L - Google Patents

Procédé de formation de presse de composant en L Download PDF

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Publication number
EP2524740A1
EP2524740A1 EP11166738A EP11166738A EP2524740A1 EP 2524740 A1 EP2524740 A1 EP 2524740A1 EP 11166738 A EP11166738 A EP 11166738A EP 11166738 A EP11166738 A EP 11166738A EP 2524740 A1 EP2524740 A1 EP 2524740A1
Authority
EP
European Patent Office
Prior art keywords
section
shape
vertical wall
metal sheet
top sheet
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP11166738A
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German (de)
English (en)
Inventor
Yasuharu Tanaka
Takashi Miyagi
Misao Ogawa
Shigeru Uchiyama
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Nippon Steel Corp
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Nippon Steel Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Nippon Steel Corp filed Critical Nippon Steel Corp
Priority to EP11166738A priority Critical patent/EP2524740A1/fr
Publication of EP2524740A1 publication Critical patent/EP2524740A1/fr
Withdrawn legal-status Critical Current

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21DWORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21D22/00Shaping without cutting, by stamping, spinning, or deep-drawing
    • B21D22/20Deep-drawing
    • B21D22/26Deep-drawing for making peculiarly, e.g. irregularly, shaped articles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21DWORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21D22/00Shaping without cutting, by stamping, spinning, or deep-drawing
    • B21D22/20Deep-drawing
    • B21D22/22Deep-drawing with devices for holding the edge of the blanks

Definitions

  • the present invention relates to a press-forming method of a component having an L shape used as a framework member or the like of an automobile.
  • FIG. 1 shows a framework structure 100 formed by joining framework members 110, 120, 130, and 140 using spot welding.
  • the framework member 110 has an L shape including a top sheet section 111, a vertical wall section 112, and a flange section 113, thereby ensuring strength and rigidity of the framework structure 100.
  • a drawing method is employed in order to suppress generation of wrinkles.
  • a blank metal sheet 300A is drawn into a formed body 300B using a die 201, a punch 202, and a blank holder 203 (holder).
  • a component 300 shown in FIG. 4A is manufactured by the drawing method, (1) the blank metal sheet 300A shown in FIG.
  • a blank metal sheet to be drawn requires high ductility.
  • a steel sheet having small ductility and high strength is used as the blank metal sheet to draw an L-shaped component, cracks or wrinkles are likely to be generated due to insufficient ductility.
  • the L-shaped component such as a front pillar reinforcement or a center pillar reinforcement is manufactured using a steel sheet having excellent ductility and relatively low strength as the blank metal sheet. Therefore, in order to ensure strength, the thickness of the blank metal sheet needs to be high, so that there is a problem with increases in component weight and costs.
  • a framework member 110' having a T shape is press-formed by combining two L shapes as shown in FIG 2 .
  • JP-A-2003-103306 JP-A-2004-154859 , JP-A-2006-015404 , and JP-A-2008-307557 .
  • bend-forming methods for manufacturing components having simple cross-sectional shapes such as a hat shape or a Z shape are described. However, such methods cannot be used for manufacturing the L-shaped component.
  • an object of the invention is to provide a press-forming method of a component having an L shape, the method being capable of press-forming a component having an L shape from a blank metal sheet with high yield even though a high-tensile material with low ductility and high strength is used for the blank metal sheet.
  • the invention uses the following methods.
  • the component having the L shape (L-shaped component) is press-formed from the blank metal sheet
  • a part of the blank metal sheet corresponding to the lower side portion of the L shape of the L-shaped component is drawn toward the vertical wall section.
  • the area of the blank metal sheet can be reduced, thereby enhancing the yield.
  • ductility needed by the blank metal sheet for forming is reduced, in addition to a steel sheet which has excellent ductility and relatively low strength and is thus typically used, a steel sheet having relatively low ductility and high strength can be used as the blank metal sheet. Accordingly, the thickness of the blank metal sheet can be reduced, thereby contributing to a reduction in weight of the automobile.
  • a component having a top sheet section 11, and a vertical wall section 12 which is connected to the top sheet section 11 with a bent section 15 having a part 15a curved in an arc shape and has a flange section 13 on the opposite side to the bent section 15, is formed of a steel sheet (a blank metal sheet).
  • the top sheet section 11 exists on the outside of the arc of the vertical wall section 12.
  • the vertical wall section 12 and the flange section 13 are formed in a state where sliding (in-plane movement) of at least a part of the area of the steel sheet S (at least a part of the area of the steel sheet S corresponding to the top sheet section 11) is allowed on a part of a die 51 corresponding to the top sheet section 11. More specifically, the steel sheet S is disposed between the die 51 or a pad 52 and a bending die 53, and in a state where the pad 52 is caused to approach or come in contact with the steel sheet S, the vertical wall section 12 and the flange section 13 are formed while at least a part of the steel sheet S is caused to slide on the part of the die 51 corresponding to the top sheet section 11.
  • the state where the pad is caused to approach the steel sheet means a state where the steel sheet and the pad do not come in contact with each other when the steel sheet slides on the part of the die corresponding to the top sheet section and the steel sheet and the pad come in contact with each other when the steel sheet is likely to undergo out-of-plane deformation (or buckling) on the corresponding part.
  • a part of a metal sheet S may be pressurized as an out-of-plane deformation suppressing area (area F) at a predetermined load pressure by the pad 52.
  • the pressure mentioned herein is an average surface pressure obtained by dividing a pad pressurizing force by the area of the contact portion of the pad 52 and the steel sheet S, and may be slightly locally uneven.
  • a portion of the steel sheet S that approaches or comes in contact with an out-of-plane suppressing area of the pad as the out-of-plane deformation suppressing area may be formed in a state where a clearance between the pad 52 and the die 51 is equal to or greater than the thickness of the steel sheet S and is maintained to be equal to or smaller than 1.1 times the thickness thereof.
  • the steel sheet S can sufficiently slide (perform in-plane movement) in the die unit 50 since an excessive surface pressure is not applied to the sheet S.
  • a surplus thickness is provided in the top sheet section 11 as the forming proceeds and thus a force to cause the steel sheet S to undergo out-of-plane deformation is exerted, out-of-plane deformation of the steel sheet S is restrained by the pad 52, so that generation of cracks or wrinkles can be suppressed.
  • the portion being caused to approach or come in contact with the out-of-plane suppressing area of the pad 52 as the out-of-plane deformation suppressing area (the area F), when the portion is formed in the state where the clearance between the pad 52 and the die 51 is equal to or greater than the thickness of the sheet and is maintained to be equal to or smaller than 1.1 times the thickness of the sheet, small winkles are generated if the clearance between the pad 52 and the die 51 is equal to or greater than 1.03 times the thickness of the sheet. Therefore, it is more preferable that the clearance between the pad 52 and the die 51 be equal to or greater than the thickness of the sheet and equal to or smaller than 1.03 times the thickness of the sheet.
  • An L-shaped component 10 has the planar top sheet section 11 having an L shape, the vertical wall section 12, and the flange section 13 as shown in FIG. 6 .
  • the top sheet section 11 is connected to the vertical wall section 12 with the bent section 15 including the part 15a curved in the arc.
  • the arc of the part 15a curved in the arc shape has a shape having a predetermined curvature, an elliptical shape, a shape having a plurality of curvatures, a shape having a straight portion, or the like as viewed in the press direction.
  • the top sheet section 11 exists on the outside of the arc of the part 15a curved in the arc shape, and the flange section 13 exists on the inside of the arc (on the center point side of the arc) of the part 15a curved in the arc shape.
  • the top sheet section 11 does not need to be completely planar, and may have various additional shapes on the basis of the design of a press product.
  • the end portion at a position distant from the end portion (the end portion of the lower side of the L shape) of the bent section 15 is referred to as an end portion A (first end portion), and the end portion at a position close to the end portion (the end portion of the lower side of the L shape) of the bent section 15 is referred to as an end portion B (second end portion).
  • the bent section 15 has a part 15b extending substantially in a straight shape from the outside of the end portion A (the opposite side to the end portion B), and a part 15c extending substantially in a straight shape from the outside of the end portion B (the opposite side of the end portion A).
  • the end portion B of the part 15a curved in the arc shape is the same as an end portion of the bent section 15.
  • the part 15c extending substantially in the straight shape from the outside of the end portion B (the opposite side of the end portion A) does not exist.
  • the steel sheet S has a shape from which the L-shaped component 10 is developed. That is, the steel sheet S has parts corresponding to the top sheet section 11, the vertical wall section 12, the flange section 13, and the like in the L-shaped component 10.
  • a pre-processed steel sheet (blank metal sheet) which is subjected to pre-processing such as press-forming, bend-forming, or perforating may also be used.
  • the end portion A which is one end portion of the part 15a curved in the arc shape of the bent section 15 when viewed in a direction perpendicular to a surface of the top sheet section 11 (press direction)
  • an area (a hatched portion of FIG 10 ) that abuts on the top sheet surface of the die 51 (a surface corresponding to the top sheet section of the steel sheet S) in an area of a side including the end portion B (second end portion) which is the other end portion of the part 15a curved in the arc shape of the bent section 15 be pressurized as an out-of-plane deformation suppressing area (area F).
  • a pad having a shape to include, at least from a part of the out-of-plane deformation suppressing area (the area F) which abuts on a boundary line with the part of the bent section curved in the arc shape, an area within 5 mm from the boundary line, and to cover an area of 50% or greater of the out-of-plane deformation suppressing area (the area F) may be used.
  • a pad in which pressurizing surfaces are separated may be used.
  • an area within at least 5 mm from the boundary line be pressurized by the pad 52.
  • wrinkles are more likely to be generated in the top sheet section 11.
  • the generation of wrinkles does not have a significant effect on product strength compared to the generation of cracks.
  • the die unit 50 used in the press-forming method according to this embodiment is shown.
  • the die unit 50 includes the die 51, the pad 52, and the bending die 53.
  • a driving mechanism of the pad 52 used to pressurize the steel sheet S so that in-plane movement can be allowed in the part corresponding to the out-of-plane deformation suppressing area (the area F) may be a spring or a hydraulic pressure, and a cushion gas may be used as the pad 52.
  • a driving mechanism of the pad 52 used to form the vertical wall section 12 and the flange section 13 in a state where a clearance of the pad 52 and the die 51 is maintained to be equal to or greater than the thickness of the steel sheet S and to be equal to or smaller than 1.1 times the thickness thereof may be a motor cylinder, a hydraulic servo apparatus, or the like.
  • the steel sheet S having a shape from which a formed body is developed which is shown in FIG 9A
  • the die 51 is installed on the die 51 as shown in FIG. 9B .
  • the bending die 53 is lowered in the press direction P, such that the vertical wall section 12 and the flange section 13 are formed as shown in FIG. 9C .
  • the steel sheet S As described above, as the bending die 53 is lowered in the press direction, the steel sheet S is deformed along the shapes of the vertical wall section 12 and the flange section 13.
  • the part corresponding to the vertical wall section 12 of the lower side portion of the L shape flows into the vertical wall section 12. That is, since the position in the steel sheet S corresponding to the top sheet section 11 of the lower side portion of the L shape is stretched, generation of wrinkles in the top sheet section 11, in which wrinkles are more likely to be generated due to an inflow of an excessive metal material during typical drawing, is suppressed.
  • the shape of the steel sheet S may be a shape in which an end portion of at least a part thereof is on the same plane as the top sheet section 11 (a shape in which the end portion is not wound during press-forming). That is, as shown in FIG. 10 , it is preferable that the end portion of the part corresponding to the out-of-plane deformation suppressing area (the area F) in the steel sheet S be on the same plane as the top sheet section 11.
  • the height H of the vertical wall section 12 to be formed is smaller than 0.2 times the length of the part 15a curved in the arc shape of the bent section 15 or smaller than 20 mm, wrinkles are more likely to be generated in the vertical wall section 12. Therefore, it is preferable that the height H of the vertical wall section 12 be equal to or greater than 0.2 times the length of the part 15a curved in the arc shape of the bent section 15 or equal to or greater than 20 mm.
  • a steel sheet having high ductility and relatively low strength for example, a steel sheet having a breaking strength of about 1,600 MPa
  • even a steel sheet having low ductility and relatively high strength for example, a steel sheet having a breaking strength of about 400 MPa
  • a high-strength steel sheet having a breaking strength of equal to or higher than 400 MPa and equal to or lower than 1,600 MPa may be used.
  • the width h i of the flange section 13 on the upper side from the center of the curve of the vertical wall may be equal to or greater than 25 mm and equal to or smaller than 100 mm. More specifically, it is preferable that the press-forming be performed so that in the flange section 13, in a portion of the vertical wall section 12 connected to the part 15a curved in the arc shape of the bent section 15, the widths h i of a flange portion 13a of the end portion A side from a center line C in a longitudinal direction (peripheral direction) of the flange section 13 of the portion connected to the opposite side to the top sheet section 11 and a flange portion 13b (that is, an area O) in front of the flange portion of the end portion A side by 50 mm are equal to or greater than 25 mm and equal to or smaller than 100 mm.
  • the width h i is defined as a shortest distance from an arbitrary position in the flange end portions of the flange portions 13a and 13b, to a position on the boundary line between the vertical wall section and the flange section.
  • width h i is equal to and greater than 25 mm and equal to and smaller than 100 mm, generation of wrinkles and cracks in the flange section 13 can be suppressed.
  • a radius of curvature of a maximum curvature portion of the curve of the vertical wall section 12 that is, a radius (RMAX) of curvature of a maximum curvature portion of the boundary line between the part 15a curved in the arc shape of the bent section 15 and the top sheet section 11, be equal to or greater than 5 mm and equal to or smaller than 300 mm.
  • the radius of curvature of the maximum curvature portion is greater than 300 mm, the length of the front end of the lower portion of the L shape is lengthened and thus the distance drawn into the inside (the vertical wall section 12) of the L shape is increased during press-forming, so that a sliding distance between the die unit 50 and the steel sheet S is increased. Therefore, wear of the die unit is accelerated, resulting in a reduction in the life-span of the die. It is more preferable that the radius of curvature of the maximum curvature portion be smaller than 100 mm.
  • the forming method of a member having a single L shape is exemplified.
  • the invention can also be applied to forming of a component having a shape of two L characters (a T-shaped component and the like), or a component having a shape of two or more L characters (a Y-shaped component and the like). That is, when a shape having a plurality of L characters is to be press-formed, forming may be performed by the forming method of the L shape described above to form a shape of a single L character, a plurality of L characters, or any L character.
  • the top sheet section 11 may have an L shape, a T shape, or a Y shape.
  • the top sheet section 11 may have a T shape or Y shape which is left-right asymmetric.
  • a vertical positional relationship between the die 51 and the bending die 53 is not limited to that of the invention.
  • blank metal sheet according to the invention is not limited only to the steel sheet S.
  • blank metal sheets suitable for press-forming such as, an aluminum sheet or a Cu-Al alloy sheet may also be used.
  • Examples 1 to 52 formed bodies each of which has a top sheet section, a vertical wall section, and a flange section were formed using a die unit having a pad mechanism.
  • Perspective views ((a) in the figures) of the formed bodies formed in Examples 1 to 52, and plan views of an area O (an area of (arc length)/2 mm+50 mm), an area F (an out-of-plane deformation suppressing area), and a pressurized position which was actually pressurized and is shown as hatched sections ((b), (c), and (d) in the figures) are shown in FIGS. 11 to 32 .
  • the unit of dimensions indicated in FIGS. 11 to 32 is mm.
  • the end portion A (the first end portion) and the end portion B (the second end portion) of the formed body which is press-formed in each example are shown as A and B in the figures, respectively.
  • top sheet shape "arc length (mm)”, “arc length ⁇ 0.2”, “radius of curvature of maximum curvature portion of arc”, “height H of vertical wall section”, “A end flange width (mm)”, “shape of arc”, “winding of end portion”, “shape of front of A end”, and “additional shape of top sheet section” are shown.
  • Examples 1 and 41 a formed body shown in FIG. 11 was press-formed by employing an appropriate forming condition. No crack and wrinkle was generated in the formed body.
  • Example 2 the formed body shown in FIG. 11 was press-formed by setting the pad load pressure to be lower than that of Example 1. In the formed body, wrinkles were generated in the top sheet section and small wrinkles were generated in the vertical wall section. However, since no crack was generated, there was no problem with product strength.
  • Example 3 the formed bodies shown in FIG. 11 were press-formed by setting the pad load pressure to be higher than that of Example 1. Accordingly, the blank metal sheet could not sufficiently slide (perform in-plane movement) in the pressurized position, and cracks were generated in the flange section.
  • Example 45 to 52 the formed bodies shown in FIG. 11 were press-formed by setting the ratio of the clearance between the pad and the die to the sheet thickness (the clearance between the pad and the die/the sheet thickness) to 1.00 to 2.00.
  • the ratio of the clearance between the pad and the die to the sheet thickness is set to 1.80
  • Example 52 in which the ratio of the clearance between the pad and the die to the sheet thickness is set to 2.00, buckling deformation had occurred in the top sheet section, so that a desired product shape could not be obtained.
  • Example 4 a formed body shown in FIG. 12 was press-formed by pressurizing an area other than the out-of-plane deformation suppressing area (the area F) with the pad.
  • the area F the out-of-plane deformation suppressing area
  • Example 5 a formed body shown in FIG 13 was press-formed by pressurizing an area including the entire out-of-plane suppressing area (the area F) with the pad. In the formed body, no winkle and crack was generated.
  • Example 6 a formed body shown in FIG. 14 was press-formed.
  • the end portion of the part corresponding to the out-of-plane formation suppressing (the area F) does not exist on the same plane as the top sheet section, that is, since the end portion is wound, cracks were generated in the flange section.
  • Example 7 formed bodies shown in FIGS. 15 , 16 , 17 , and 18 were press-formed.
  • the arc is elliptical (Example 7)
  • the arc has a plurality of curvatures (R) (Example 8)
  • the arc has a straight portion (Example 9)
  • the front end of the arc is the end portion of the bent section (Example 10)
  • Example 11 formed bodies shown in FIGS. 19 , 20 , and 21 were press-formed.
  • the product designs even when the shape of the front of the A end is non-straight (Examples 11 and 13), or the top sheet section has an additional shape (Example 13), it could be seen that the effects of the invention were sufficiently obtained.
  • the area F the entire out-of-plane deformation suppressing area
  • the area F the entire out-of-plane deformation suppressing area
  • the area F even when the entire out-of-plane deformation suppressing area (the area F) could not be pressurized by the pad since a small additional shape existed in a part of the out-of-plane deformation suppressing area (the area F), it could be seen that the effects of the invention were obtained.
  • Example 14 formed bodies shown in FIG 22 were press-formed by setting the height H of the vertical wall section to 10 mm (Example 14), 15 mm (Example 15), 20 mm (Example 16), and 30 mm (Example 17). In these examples, it could be seen that wrinkles of the vertical wall section could be suppressed by setting the height H of the vertical wall section to 20 mm or greater. In Examples 14 and 15 in which the heights of the vertical wall sections were smaller than 20 mm, winkles were generated in the vertical wall sections. However, since no crack was generated, there was no problem with product strength.
  • the height H of the vertical wall section it could be seen that by setting the height H of the vertical wall section to be equal to or greater than 0.2 times the arc length, wrinkles of the vertical wall section could be suppressed even though the height of the vertical wall section was smaller than 20 mm.
  • Example 18 in which the height H of the vertical wall section is smaller than 0.2 times the arc length, wrinkles were generated in the vertical wall section. However, since no crack was generated, there was no problem with product strength.
  • Example 21 to 23 formed bodies shown in FIGS. 24 , 25 , and 26 were press-formed by pressurizing, in a part which abuts on a boundary line between the top sheet section and the part curved in the arc shape of the bent section, an area within 3 mm (Example 21), 5 mm (Example 22), or 8 mm (Example 23) from the boundary line, with the pad.
  • an area within 3 mm Example 21
  • 5 mm Example 22
  • 8 mm Example 23
  • Example 24 formed bodies shown in FIG. 27 were press-formed by setting the flange width at the A end to 20 mm (Example 24), 25 mm (Example 25), 80 mm (Example 26), 100 mm (Example 27), and 120 mm (Example 28).
  • the flange width it could be seen that by setting the flange width to be in the range of 25 mm to 100 mm, generation of wrinkles and cracks could be suppressed.
  • necking had occurred in the flange section by setting the flange width to 20 mm
  • Example 28 significant wrinkles were generated in the flange section and necking had occurred in the top sheet section by setting the flange width to 120 mm.
  • no crack was exhibited, there was no significant problem with strength characteristics.
  • Examples 29 to 32 formed bodies shown in FIG. 28 were press-formed by setting the radius of curvature of the maximum curvature portion of the arc to 3 mm (Example 29), 5 mm (Example 30), 10 mm (Example 31), and 20 mm (Example 31) when the arc has a straight portion (R+Straight+R).
  • the radius of curvature of the maximum curvature portion of the arc it could be seen that by setting the radius of curvature of the maximum curvature portion of the arc to be equal to or greater than 5 mm, wrinkles of the vertical wall section could be suppressed.
  • Examples 33 to 36 formed bodies were press-formed by setting the maximum radius of curvature of the arc to 200 mm (Example 33), 250 mm (Example 34), 300 mm (Example 35), and 350 mm (Example 36). In these examples, it could be seen that by setting the radius of curvature of the maximum curvature portion of the arc to be 300 mm or smaller, generation of wrinkles of the vertical wall section could be suppressed.
  • Example 37 a T-shaped formed body shown in FIG. 30 was press-formed.
  • a steel sheet (Example 37) obtained by pre-processing the shape shown in FIG. 33 and a pre-processed aluminum sheet (Example 38) were used.
  • the press-forming method according to the invention could be employed for forming the T-shaped formed body, and the blank metal sheet according to the invention was not limited to the steel sheet.
  • Example 39 a T-shaped formed body shown in FIG 31 , which is left-right asymmetric (Example 39), and a Y-shaped formed body shown in FIG. 32 (Example 40) were press-formed.
  • the press-forming method according to the invention could be adequately applied to forming of a formed body having a shape of one or more L characters.
  • Table 1A Corresponding figure Material Metal sheet type Sheet thickness Breaking strength (mm) MPa
  • Example 1 FIG. 11 Steel sheet 1,2 980
  • Example 2 FIG. 11 Steel sheet 1,2 980
  • Example 3 FIG. 11 Steel sheet 1,2 980
  • Example 41 FIG. 11 Steel sheet 1,6 590
  • Example 42 FIG. 11 Steel sheet 1,6 590
  • Example 43 FIG. 11 Steel sheet 1,6 590
  • Example 44 FIG. 11 Steel sheet 1,8 270
  • Example 46 FIG. 11 Steel sheet 1,2 980 Example 47 FIG. 11 Steel sheet 1,2 980
  • Example 48 FIG. 11 Steel sheet 1,2 980
  • Example 49 FIG.
  • FIG. 11 Steel sheet 1,2 980 Example 50 FIG. 11 Steel sheet 1,6 590 Example 51 FIG. 11 Steel sheet 1,6 590 Example 52 FIG. 11 Steel sheet 1,6 590 Example 4 FIG. 12 Steel sheet 1,2 980 Example 5 FIG. 13 Steel sheet 1,2 980 Example 6 FIG. 14 Steel sheet 1,2 980 Example 7 FIG. 15 Steel sheet 2,3 440 Example 8 FIG. 16 Steel sheet 0,8 590 Example 9 FIG. 17 Steel sheet 1,6 1180 Example 10 FIG. 18 Steel sheet 1,2 1380 Example 11 FIG. 19 Steel sheet 1,2 980 Example 12 FIG. 20 Steel sheet 1,2 980 Example 13 FIG. 21 Steel sheet 1,2 980 Example 14 FIG. 22 Steel sheet 1,2 980 Table 1B Corresponding figure Material Metal sheet type Sheet thickness Breaking strength (mm) MPa Example 15 FIG.
  • FIG. 22 Steel sheet 1,2 980 Example 16 FIG. 22 Steel sheet 1,2 980 Example 17 FIG. 22 Steel sheet 1,2 980 Example 18 FIG. 23 Steel sheet 0,8 980 Example 19 FIG. 23 Steel sheet 0,8 980 Example 20 FIG. 23 Steel sheet 0,8 980 Example 21 FIG. 24 Steel sheet 1,2 980 Example 22 FIG. 25 Steel sheet 1,2 980 Example 23 FIG. 26 Steel sheet 1,2 980 Example 24 FIG. 27 Steel sheet 1,2 980 Example 25 FIG. 27 Steel sheet 1,2 980 Example 26 FIG. 27 Steel sheet 1,2 980 Example 27 FIG. 27 Steel sheet 1,2 980 Example 28 FIG. 27 Steel sheet 1,2 980 Example 29 FIG. 28 Steel sheet 1,2 270 Example 30 FIG. 28 Steel sheet 1,2 270 Example 31 FIG. 28 Steel sheet 1,2 270 Example 32 FIG.
  • FIG. 29 Steel sheet 1,2 270 Example 34 FIG. 29 Steel sheet 1,2 270 Example 35 FIG. 29 Steel sheet 1,2 270 Example 36 FIG. 29 Steel sheet 1,2 270 Example 37 FIGS. 30 , 33 Steel sheet 1,8 980 Example 38 FIGS. 30 , 33 Aluminum 1,8 296 Example 39 FIG. 31 Steel sheet 1,8 980 Example 40 FIG.

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  • Mechanical Engineering (AREA)
  • Shaping Metal By Deep-Drawing, Or The Like (AREA)
EP11166738A 2011-05-19 2011-05-19 Procédé de formation de presse de composant en L Withdrawn EP2524740A1 (fr)

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Cited By (7)

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WO2014199730A1 (fr) * 2013-06-11 2014-12-18 Jfeスチール株式会社 Procédé de moulage à la presse
JP2015110237A (ja) * 2013-12-06 2015-06-18 新日鐵住金株式会社 プレス成形装置およびプレス成形方法
CN105682820A (zh) * 2013-10-30 2016-06-15 杰富意钢铁株式会社 冲压成型方法
JP2016175089A (ja) * 2015-03-18 2016-10-06 新日鐵住金株式会社 熱間プレス用金型、熱間プレス装置および熱間プレス成形品の製造方法
US9718262B2 (en) 2014-07-08 2017-08-01 Airbus Operations Limited Roll forming composite components
WO2019008880A1 (fr) * 2017-07-06 2019-01-10 Jfeスチール株式会社 Procédé de formage à la presse
JP2019202335A (ja) * 2018-05-24 2019-11-28 日本製鉄株式会社 プレス品を生産する方法

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
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