EP3263240B1 - Formed metal item including tubular part with slit, method for producing the same, and producing device and die assembly used in method for producing the same - Google Patents

Formed metal item including tubular part with slit, method for producing the same, and producing device and die assembly used in method for producing the same Download PDF

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Publication number
EP3263240B1
EP3263240B1 EP16755009.4A EP16755009A EP3263240B1 EP 3263240 B1 EP3263240 B1 EP 3263240B1 EP 16755009 A EP16755009 A EP 16755009A EP 3263240 B1 EP3263240 B1 EP 3263240B1
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EP
European Patent Office
Prior art keywords
die
cross
die assembly
cylindrical
section
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EP16755009.4A
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German (de)
English (en)
French (fr)
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EP3263240A4 (en
EP3263240A1 (en
Inventor
Masahiko Sato
Tohru Yoshida
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Nippon Steel Corp
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Nippon Steel Corp
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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
    • B21D5/00Bending sheet metal along straight lines, e.g. to form simple curves
    • B21D5/01Bending sheet metal along straight lines, e.g. to form simple curves between rams and anvils or abutments
    • B21D5/015Bending sheet metal along straight lines, e.g. to form simple curves between rams and anvils or abutments for making tubes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B21MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
    • B21CMANUFACTURE OF METAL SHEETS, WIRE, RODS, TUBES OR PROFILES, OTHERWISE THAN BY ROLLING; AUXILIARY OPERATIONS USED IN CONNECTION WITH METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL
    • B21C37/00Manufacture of metal sheets, bars, wire, tubes or like semi-manufactured products, not otherwise provided for; Manufacture of tubes of special shape
    • B21C37/06Manufacture of metal sheets, bars, wire, tubes or like semi-manufactured products, not otherwise provided for; Manufacture of tubes of special shape of tubes or metal hoses; Combined procedures for making tubes, e.g. for making multi-wall tubes
    • B21C37/08Making tubes with welded or soldered seams
    • B21C37/0815Making tubes with welded or soldered seams without continuous longitudinal movement of the sheet during the bending operation
    • 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
    • B21D37/00Tools as parts of machines covered by this subclass
    • B21D37/10Die sets; Pillar guides
    • 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
    • B21D5/00Bending sheet metal along straight lines, e.g. to form simple curves
    • B21D5/01Bending sheet metal along straight lines, e.g. to form simple curves between rams and anvils or abutments
    • 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
    • B21D5/00Bending sheet metal along straight lines, e.g. to form simple curves
    • B21D5/06Bending sheet metal along straight lines, e.g. to form simple curves by drawing procedure making use of dies or forming-rollers, e.g. making profiles
    • B21D5/10Bending sheet metal along straight lines, e.g. to form simple curves by drawing procedure making use of dies or forming-rollers, e.g. making profiles for making tubes

Definitions

  • the present invention relates to a formed metal item that includes a tubular part with a slit, a method for producing the formed metal item, and a producing device and a die assembly used in the method for producing the formed metal item.
  • Tubular components are widely used in automobile parts and household appliances. Therefore, the development of techniques to produce tubular components is promoted.
  • UO forming is known (e.g., Patent Literature 1 and 2).
  • Patent Literature 3 discloses a method for forming a hollow profile with a slot in its longitudinal direction.
  • FIG. 3 and FIG. 4 of Patent Literature 3 disclose a method in which a core (core 11) that includes a blade for forming the slot is used.
  • core 11 core 11
  • FIG. 3 and FIG. 4 of Patent Literature 3 disclose a method in which a core (core 11) that includes a blade for forming the slot is used.
  • closing and welding the slot after forming are prerequisite. Therefore, precision of the breadth of the slot and the precision of a shape before the welding are not taken in consideration.
  • the amount of spring back also varies, and thus variations in breadth of the slot occur. Therefore, in order to change the material or the thickness of the metal plate, a die assembly needs to be modified to adjust the breadth of the slot.
  • Patent Literature 1 discloses a method for forming a tubular member having a square cross section by bending a plate material.
  • a die assembly used in this method includes an upper die, a lower die, and side dices.
  • the side dices are dices for pressing side parts of a plate material in such a manner that two end edges facing each other are brought close to each other.
  • the tubular member formed by this method has a butted part that is welded after the forming. Therefore, there is no sufficient consideration is given to control of a gap between the two end edges.
  • roll forming is also known (e.g., Patent Literature 4).
  • a tubular component having a complex shape such as a varying-cross-section pipe the cross-sectional shape of which varies in its lengthwise direction.
  • press brake working As bending of a metal plate, press brake working is known (e.g., Patent Literature 5). It is conceivable that a tubular component including a gap in its butted part is formed by bending with a press brake. However, by the press brake working, it is difficult to decrease the breadth of the gap of the butted part.
  • a core is used during O forming in some cases.
  • a tubular component including a gap in its butted part is formed by making the width of a metal plate shorter than the cross-section peripheral length of a die assembly.
  • this method has a problem of a large spring back due to forming by simple bending. Therefore, also in this case, it is difficult to control the breadth of the gap of the butted part.
  • Patent Literature 6 discloses a method for producing a hollow profile from a cut blank using a UO forming technique.
  • a closed hollow profile is formed by butting two opposite edges of a cut blank against each another.
  • the redundant length is at least 1% to 10%.
  • Patent Literature 6 discloses that areas of the hollow profile abutting on an edge joint are compressed at least partly in the circumferential direction.
  • Patent Literature 6 describes that the producing method is executed using the UO forming technique.
  • Patent Literature 6 makes no specific description about how to execute the producing method. That is, Patent Literature 6 makes no disclosure about how to compress the hollow profile in the circumferential direction using the UO forming technique.
  • the method of Patent Literature 6 has no envisagement of freely controlling the width of the slit.
  • US1879077 discloses a method and means for forming pipe blanks, in which the method is for reducing a flat, rectangular blank, and more particularly one of elongated shape, to cylindrical cross-sectional form by a series of successive operations in a single set of dies.
  • DE102009017571 discloses a method involving deforming a sheet material i.e. metal sheet, before inserting the material between press tool parts in terms of U-shaped curve so that a center region of the U-shaped bent sheet material supports against one of the press tool parts and end portions of the sheet material against the other press tool part.
  • a molding surface of the latter press tool part is formed by the end portions of the sheet material during locking of the press tool parts until final shape of a pipe bend results.
  • An independent claim is also included for a device for producing pipe bends.
  • JP2014004626 discloses a method of manufacturing a different-diameter tubular component comprising a small-diameter part, large-diameter part, and a diameter variation part between the small-diameter part and large-diameter part by pressing a blank of a metal plate, the method including a process of pressing the blank into a U-shaped molding with a U-shape molding metal mold, and then pressing it into a circularly-sectioned molding with an O-shape molding metal mold.
  • JP 2004298907 discloses a forming machine which suppresses generation of oscillation by changing servo rigidity as needed in a process of sequentially working the material to be formed, since a forming tool is positioned in a predetermined position by switching a positional loop gain according to a phase during forming cycle. Further, the servo rigidity is decreased by changing the positional loop gain in order to release elastic restoration of the material. As a result, machine motion becomes smooth, compared with the case where the elastic restoration is released by moving the forming tool.
  • JP2009119466 discloses a method of working a steel sheet into a cylinder, in which a cylindrical body excellent in shape accuracy is obtained by performing roll forming utilizing the properties of a hot-rolled steel sheet.
  • the roll forming is performed by using a cut length sheet composed of an ordinary steel so that the rolling direction is the peripheral direction of the cylinder and the width direction orthogonal to the rolling direction is the axial direction of the cylinder.
  • the shape accuracy is improved and the deviation from complete roundness is reduced.
  • JP2009517222 discloses a coreless process for producing a tube from a sheet by placing it in a die made in two halves and closing them up to produce a tube with a slit. The deformation takes place in the half-dies, and the edges of the sheet are prevented from sliding forward as the die is closed up to form the slit tube.
  • an objective of the present invention is to provide a producing method capable of forming a formed metal item that includes a tubular part with a slit with precision, and capable of controlling the breadth of the slit.
  • a method in an embodiment of the present invention is a producing method for producing a formed metal item that includes a tubular part with a slit.
  • This producing method includes: (i) a step of forming a U-shaped part having a U-shaped cross section by deforming a metal plate; and (ii) a step of forming the tubular part with the slit by deforming the U-shaped part using a die assembly provided with a protruding part in such a manner that two end parts of the U-shaped part clamp the protruding part.
  • the cross-section peripheral length LH of the tubular part is made shorter than the cross-section length LU of the U-shaped part
  • the step (ii) includes:
  • a formed metal item in an embodiment of the present invention is a formed metal item that includes a tubular part with a slit.
  • a variation S in Vickers hardness in the thickness direction of the cross section of the tubular part is expressed by the following expression, an average value of variations S in a circumferential direction is less than 0.4.
  • S Bmax ⁇ Bmin / Bmax
  • Bmin is a minimum value of the Vickers hardnesses in the thickness direction of the cross section.
  • Bmax is a maximum value of the Vickers hardnesses in the thickness direction of the cross section.
  • a die assembly in an embodiment of the present invention is a die assembly for producing a formed metal item that includes a tubular part with a slit.
  • This die assembly includes a first die that includes a protruding part for forming the slit, and a second die.
  • the first and second dies include first and second pressing surfaces, respectively, which are configured to deform a U-shaped part having a U-shaped cross section in such a manner that two end parts of the U-shaped part clamp the protruding part to form a cylindrical-shape portion with a gap, the gap being to be the slit.
  • the die assembly has a configuration to press the outer peripheral surface of the cylindrical-shape portion while the two end parts are clamping the protruding part so that the cross-section peripheral length of the cylindrical-shape portion is made short.
  • a formed metal item that includes a tubular part with a slit with precision it is possible to form a formed metal item that includes a tubular part with a slit with precision, and to control the breadth of the slit.
  • a formed metal item that includes a tubular part with a slit formed with precision is obtained.
  • a producing device and a die assembly suitably used in a producing method according to the present invention are obtained.
  • a producing method according to the present invention is a method for producing a formed metal item that includes a tubular part with a slit. Matters described about the producing method according to the present invention are applicable to a formed metal item, a producing device, and a die assembly according to the present invention.
  • the formed metal item may include a part other than the tubular part with a slit.
  • the formed metal item may be constituted by only the tubular part with a slit.
  • the formed metal item in this case is a tubular formed item with a slit. Examples of the formed metal item to be produced will be described later.
  • the producing method according to the present invention includes step (i) and step (ii), which will be described below.
  • step (i) a metal plate is deformed, whereby a U-shaped part, which has a U-shaped cross section, is formed.
  • Step (i) has no special limitation, and U forming used in conventional UO forming may be applied thereto.
  • the method for U forming has no special limitation as long as the method allows the metal plate to be formed to have a U-shaped cross section. Examples of the U-forming method include press forming, roll forming, and other kinds of forming.
  • the U forming may be performed in a plurality of steps.
  • working to bend the ends of the metal plate working such as what is called C forming
  • trimming (cutting) of the U-shaped part may be performed.
  • the cross section of a tubular part means a cross section in the circumferential direction of the tubular part, unless otherwise noted.
  • the cross section of the tubular part means a cross section in a direction perpendicular to the axis direction (normally the lengthwise direction) of the tubular part.
  • the same is true for the cross section of the U-shaped part, the cross section of a cylindrical-shape portion, and the cross section of a pressing surface of a die assembly.
  • the pressing surface of a die assembly means a surface of the die assembly that is to come into contact with the outer peripheral surface of the cylindrical-shape portion (or the tubular part), unless otherwise noted.
  • the cross-section peripheral length of the pressing surface of the die assembly means the total cross-section length of the pressing surfaces of the plurality of members.
  • the metal plate to be subjected to the forming by the producing method according to the present invention may be hereinafter referred to as a blank.
  • the metal plate (blank) has no special limitation as long as the metal plate allows the forming.
  • the metal plate include a steel plate, for example, a hot-rolled steel plate, a cold-rolled steel plate, a plated steel plate, and other kinds of plates.
  • examples of the metal plate include a metal plate made by joining a plurality of metal plates together (what is called a tailored blank).
  • the tailored blank may be made by joining a plurality of metal plates together in the axis direction of the resultant tubular part, or may be made by joining a plurality of metal plates together in the circumferential direction of the resultant tubular part.
  • the blank use may be made of a twin gauge plate, the thickness of which differs from area to area. Further, as the blank, use may be made of what is called a stacked plate. Examples of the stacked plate include a plate made by stacking a plurality of metal plates and a plate made by overlaying a nonmetallic row material on a metal plate. That is, the formed metal item may contain a material other than a metal plate.
  • the metal plate may be a thin-wall metal plate or a high-tensile steel plate (what is called a high-tensile material). These plates tend to have large spring backs and are suitable in particular for the present invention.
  • the thin-wall metal plate include a metal plate in which the ratio of the thickness to the equivalent diameter, of the metal plate, is 10% or less.
  • the equivalent diameter is a value obtained by dividing the cross-section peripheral length of the tubular part by 3.14.
  • the tensile strength of the high-tensile material is preferably 300 MPa or more and may be 440 MPa or more (e.g. 490 MPa or more or 780 MPa or more).
  • the upper limit of the tensile strength has no special limitation and may be 2000 MPa or less.
  • the material of the metal plate has no special limitation as long as the metal plate allows the forming.
  • Examples of the material of the metal plate include Fe-based, Al-based, Cu-based, and Ti-based metal, and other kinds of metals.
  • the thickness of the metal plate has no special limitation as long as the thickness allows the forming.
  • the thickness of the metal plate is selected in consideration of the material of the metal plate, the shape of the formed metal item, the usage of the formed metal item, and other factors. As an example, the thickness of the metal plate may fall within a range from 0.4 to 5 mm (e.g., a range from 0.5 to 3 mm or a range from 1 to 3 mm, etc.).
  • the shape of the metal plate is selected in conformity with an intended shape of the formed metal item.
  • a cross-section peripheral length LH of the tubular part is made shorter than a cross-section length LU of the U-shaped part.
  • a width W of a portion to be made into the tubular part is determined in consideration of a compressibility C, which will be described later.
  • the tubular part with a slit is formed by deforming the U-shaped part using a die assembly provided with a protruding part in such a manner that two end parts of the U-shaped part clamp the protruding part.
  • the cross-section peripheral length LH of the tubular part is made shorter than the cross-section length LU of the U-shaped part. The metal plate constituting the tubular part is thereby compressed in the circumferential direction. Consequently, the spring back of the tubular part is suppressed, which allows the breadth of the slit to be controlled with precision.
  • step (ii) The gap between the two end parts that are butted against each another across the protruding part (the two end parts of the U-shaped part) serves as a slit. That is, a formed metal item including a tubular part with a slit is produced by step (ii). Of course, the formed metal item obtained by step (ii) may be further worked.
  • the difference between the cross-section peripheral length LH of the tubular part and the cross-section length LU of the U-shaped part is preferably 0.2% or more of the cross-section length LU of the U-shaped part.
  • the cross-section length LU of the U-shaped part and the cross-section peripheral length LH of the tubular part satisfy an expression of 0.2 ⁇ 100 ⁇ (LU - LH) / LU. If the difference is excessively small, the effect of suppressing the spring back and the effect of forming the tubular part with precision may not be obtained.
  • the value of 100 ⁇ (LU - LH) / LU may be referred to as a compressibility C(%) of the tubular part.
  • the compressibility C of the tubular part may be 0.5% or more.
  • the compressibility C may be set at 2% or smaller or may be set at less than 1%.
  • the compressibility C is preferably set at less than 1%.
  • an expression of 0.2 ⁇ 100 ⁇ (LU - LH) / LU ⁇ 1 is satisfied.
  • the difference (LU - LH) between the cross-section peripheral length LH of the tubular part and the cross-section length LU of the U-shaped part is excessively large, there is the risk that buckling (folding of the metal plate) occurs or that the metal plate is caught in a contact portion between an upper die and a lower die. Meanwhile, the larger the thickness of the metal plate, buckling is more difficult to bring about even when the compressibility C is increased. In addition, the smaller the thickness of the metal plate, the greater the effect obtained by the compression. From the viewpoint of this respect, it is preferable that the difference between the cross-section peripheral length LH and the cross-section length LU of the U-shaped part is determined in consideration of the thickness of the metal plate.
  • the difference between the cross-section peripheral length LH of the tubular part and the cross-section length LU of the U-shaped part may be set at 8t or smaller.
  • the difference between the cross-section peripheral length LH of the tubular part and the cross-section length LU of the U-shaped part may be set at 0.1t or larger.
  • the above compressibility C is 0.2% or more, and the difference between the cross-section peripheral length LH and the cross-section length LU is 8t or smaller. In another preferable example, the above compressibility C is 0.2% or more and 2% or less.
  • the compressibility C is preferably 0.2% or more and less than 1% (e.g., 0.2% or more and less than 0.5%).
  • the compressibility C may be determined in consideration of a yield stress ⁇ (MPa) and the thickness t (mm) of the metal plate (blank) constituting the tubular part.
  • the aforementioned compressibility C(%) may satisfy the following expression.
  • any of the aforementioned lower limits may be adopted as the lower limit of the compressibility C.
  • the metal plate satisfying the following expression may have any thickness and may have a thickness that falls within the aforementioned range (e.g., range from 0.4 to 5 mm).
  • Step (ii) includes the following steps (ii-1) and (ii-2).
  • step (ii-1) a cylindrical-shape portion is formed by deforming the U-shaped part using a die assembly in such a manner that the two end parts of the U-shaped part clamp the protruding part, the cylindrical-shape portion being to be the tubular part.
  • the cylindrical-shape portion is a precursor of the tubular part obtained by the step (ii), which can be rephrased into a first tubular part or a tubular part precursor.
  • step (ii-2) the outer peripheral surface of the cylindrical-shape portion is pressed with the two end part clamping the protruding part of the die assembly, and the cross-section peripheral length LT of the cylindrical-shape portion is thereby shortened.
  • the cross-section peripheral length LH of the tubular part is made shorter than the cross-section length LU of the U-shaped part. That is, by step (ii-2), the metal plate constituting the tubular part is compressed in the circumferential direction.
  • Example (A) and example (B) are examples including steps (ii-1) and (ii-2).
  • a die assembly (a) used in the example (A) has the following configurations (a-1), (a-2), and (a-3).
  • both of the first and second dies may be separable.
  • only the first die may be separable, or only the second die may be separable.
  • the cross-section peripheral length LH of the tubular part can be finely adjusted. As a result, it is possible to reduce variations more in compressive stress acting on the tubular part. Consequently, the slit can be formed with more precision.
  • the first die is separable, the first die is separable into a first die member and a second die member.
  • the protruding part may be configured by a first protruding part included in the first die member and a second protruding part included in the second die member.
  • step (ii-1) of the example (A) the cylindrical-shape portion is formed by deforming the U-shaped part using the die assembly (a) while a plurality of die members are separated.
  • step (ii-2) the outer peripheral surface of the cylindrical-shape portion is pressed by bringing the plurality of die members close to each other, which shortens the cross-section peripheral length LT of the cylindrical-shape portion. With this configuration, the metal plate constituting the tubular part is compressed in the circumferential direction.
  • the die assembly (a) moves only in a vertical direction in step (ii-1), and the die assembly (a) moves only in a horizontal direction in step (ii-2).
  • the upper die is caused to move to a bottom dead point in step (ii-1).
  • step (ii-2) the separated plurality of die members are caused to move in the horizontal direction.
  • a die assembly (b) used in the example (B) has the following configurations (b-1), (b-2), and (b-3).
  • the first and second dies may each include the movable part.
  • the first and second dies include first and second movable parts, respectively, the first and second movable parts being movable in the pressing direction (the vertical direction).
  • the first movable part included in the first die may include a protruding part for forming the slit.
  • at least one of the first and second dies includes first and second movable parts that are movable in a direction orthogonal to the pressing direction.
  • the first and second movable parts are disposed in such a manner as to face each other across the cylindrical-shape portion.
  • the two movable parts press the outer peripheral surface of the cylindrical-shape portion, which can compress the cylindrical-shape portion in question in the circumferential direction.
  • the pressing direction means a direction in which the body part of the die assembly moves during the forming.
  • step (ii-1) of the example (B) the U-shaped part is deformed using the die assembly while the pressing surface of the movable part does not project from the pressing surface of the body part.
  • step (ii-2) the outer peripheral surface of the cylindrical-shape portion is pressed by causing the pressing surface of the movable part to project from the pressing surface of the body part, which shortens the cross-section peripheral length LT of the cylindrical-shape portion. With this configuration, the metal plate constituting the tubular part is compressed in the circumferential direction.
  • the body part is not caused to move, and only the movable part is caused to move.
  • a die assembly (c) used in the example (C) not in accordance with the present invention has the following configurations.
  • the first die and the second die constituting the die assembly (c) are each basically a single piece.
  • the protruding part of the first die may be however made replaceable.
  • the U-shaped part is deformed only by bringing the first die and the second die close to each other in step (ii), whereby the tubular part with a slit is formed.
  • the example (C) has a simple configuration of the die assembly and has an advantage that the production of the formed metal item is easy.
  • the die assembly may include a pressing surface corresponding to the outer peripheral surface of the tubular part, and the cross-section peripheral length of the pressing surface may be shorter than the cross-section length LU of the U-shaped part.
  • the pressing surface of the die assembly presses the outer peripheral surface of the U-shaped part to form the tubular part, whereby the cross-section peripheral length LH of the tubular part can be made shorter than the cross-section length LU of the U-shaped part.
  • the above die assembly (c) has this configuration, and the above die assembly (a) also has this configuration basically.
  • the above die assembly (b) may or may not have this configuration.
  • the cross-section peripheral length of the pressing surface of the die assembly means the total cross-section length of the pressing surfaces of a plurality of members that constitute the die assembly.
  • the cross-section peripheral length of the pressing surface of the die assembly is not considerably different from the cross-section peripheral length LH of the tubular part when the tubular part with a slit is formed by closing the die assembly completely.
  • the cross-section peripheral length LH of the tubular part can be substituted by the cross-section peripheral length of the pressing surface of the die assembly.
  • the cross-section peripheral length LH of the tubular part can be substituted by the cross-section peripheral length of the pressing surface of the die assembly.
  • Step (ii) of the producing method according to the present invention is executed typically without using a core, and may be executed, for example, without using a core that is to come into contact with most of an inner peripheral surface (e.g., 50% or more of the area of the inner peripheral surface) of the tubular part (or the cylindrical-shape portion).
  • the tubular part becomes easy to compress uniformly in the circumferential direction.
  • a metal plate between the die assembly and the core becomes difficult to compress in the circumferential direction.
  • the core may be used in step (ii) as necessary. By using the core, it is possible to stably form a formed metal item having a complex cross-sectional shape in the circumferential direction.
  • the core may be used for a stable forming.
  • the core may be disposed over the entire part to be made into the tubular part or over only a part to be made into the tubular part.
  • the formed metal item may be further worked after step (ii). For example, a protrusion or a flat part may be added to the formed metal item, or a hole may be opened in the formed metal item.
  • the producing method according to the present invention is aimed at producing a formed metal item that includes a tubular part with a gap in a butted part.
  • the slit (the butted part with a gap) is basically not welded after step (ii).
  • part of the butted part may be welded.
  • part of the butted part may be subjected to tack welding.
  • the formed metal item according to the present invention includes a tubular part with a slit. From a viewpoint, this tubular part is a tubular part having a gap in a butted part.
  • the formed metal item according to the present invention is produced by the producing method according to the present invention. As to matters about this formed metal item that have already described in another part of the description, the redundant description thereof may be omitted.
  • the matters described about the formed metal item according to the present invention are applicable to the producing method, the producing device, and the die assembly according to the present invention.
  • the formed metal item according to the present invention may include a part other than the tubular part with a slit.
  • the formed metal item may be constituted by only the tubular part with a slit.
  • the formed metal item in this case is a tubular formed item with a slit.
  • the slit is normally formed along the axis direction (normally the lengthwise direction) of the tubular part.
  • the slit may be formed in the entire tubular part or may be formed only in part of the tubular part.
  • the formed metal item may have a slit across the overall length of the butted part, or may have a slit only in part of the butted part.
  • the shape of the tubular part with a slit has no special limitation as long as the shape is formable by the method according to the present invention.
  • the tubular part has no special limitation in its cross-sectional shape and may have various shapes such as a round, an ellipse, a quadrilateral, a vertically asymmetrical shape, and a horizontally asymmetric shape.
  • the tubular part may be round-tube-shaped or square-tube-shaped.
  • Examples of the shape of the tubular part include a straight pipe, a curved pipe, a varying-diameter pipe the outer diameter of which varies in its lengthwise direction, a varying-cross-section pipe the cross-sectional shape of which varies in its lengthwise direction, and the other kinds of pipes.
  • examples of the tubular part include pipes illustrated in FIG. 9A, FIG. 9B, FIG. 9C, FIG. 9D, and FIG. 9E (tubular part 1e). In each of these pipes, a slit 3 is formed in a butted part 2.
  • the pipe illustrated in FIG. 9A is a straight pipe the cross-sectional shape in the circumferential direction of which is round-shaped.
  • the pipe illustrated in FIG. 9B is a curved pipe the cross-sectional shape in the circumferential direction of which is round-shaped.
  • the pipe illustrated in FIG. 9C is a trumpet-shaped varying-diameter pipe the cross-sectional shape in the circumferential direction of which is round-shaped.
  • the pipe illustrated in FIG. 9D is a varying-cross-section pipe the cross-sectional shape in the circumferential direction of which varies from a round shape to a quadrilateral shape.
  • the pipe illustrated in FIG. 9A is a straight pipe the cross-sectional shape in the circumferential direction of which is round-shaped.
  • the pipe illustrated in FIG. 9B is a curved pipe the cross-sectional shape in the circumferential direction of which is round-shaped.
  • the pipe illustrated in FIG. 9C is a trumpet-shaped varying-diameter pipe the
  • FIG. 9E is a pipe having the cross-sectional shape in the circumferential direction of which is vertically asymmetrical and horizontally asymmetric.
  • the pipe illustrated in FIG. 9E is a pipe formed of a tailored blank made by joining different metal plates in the circumferential direction.
  • a pipe the cross-sectional shape in the circumferential direction of which is a horizontally asymmetric shape and a pipe using a tailored blank as illustrated in FIG. 9E are difficult to form into by conventional UO forming.
  • the die assembly according to the present invention it is possible to form pipes of various shapes or various types of blanks.
  • the formed metal item according to the present invention is obtained by subjecting a metal plate (blank) to forming. For this reason, the material of the formed metal item is the same as the material of the blank. Furthermore, the thickness of the formed metal item is substantially the same as the thickness of the blank. Therefore, the thickness of the formed metal item (the thickness of the tubular part) may fall within the range exemplified as the thickness of the blank. Some of the physical properties of the formed metal item change from the physical properties of the blank in a working step. In the formed metal item according to the present invention, in particular, since the tubular part is compressed in the circumferential direction, the physical properties thereby change.
  • Bmin is a minimum value of the Vickers hardnesses in the thickness direction of the cross section of the tubular part.
  • Bmax is a maximum value of the Vickers hardnesses in the thickness direction of the cross section.
  • the average value of the variations S in the circumferential direction is the average value of variations S that are measured at three points of one cross section of the tubular part (a cross section in the circumferential direction).
  • the three positions for the measurement are a first position that is in the vicinity of the slit of the tubular part, a second position that is the furthest from the first position in the circumferential direction, and a third position that is midway between the first position and the second position.
  • the first, second, and third positions lie at about 180°, 0°, and 90°, respectively.
  • the first position is set at a distance within a range of 5 mm or shorter from an end part facing the slit.
  • a cross-section peripheral length LH of the tubular part is made shorter than a cross-section length LU of the U-shaped part. Therefore, compressive stress acts on the entire tubular part in the thickness direction, and a variation in compressive stress acting on the tubular part in the circumferential direction is small. For this reason, by forming the tubular part by the producing method according to the present invention, it is possible to increase a Vickers hardness over the entire cross section of the tubular part. As a result, it is possible to reduce the variation in Vickers hardness over the entire cross section of the tubular part. Decreasing the variation in Vickers hardness is useful for the enhancement of the durability and reliability formed metal item with the tubular part.
  • all of the variations S measured at the aforementioned three positions are less than 0.4 (e.g., less than 0.2). With this configuration, the enhancement of the durability and reliability can be expected.
  • the tubular part is cut in the circumferential direction, and the cut surface is subject to mechanical polishing until the cut surface becomes a mirror plane.
  • the cut surface is dissolved up to a depth of 30 to 80 ⁇ m from the surface of the cut surface, by chemical polishing or electropolishing. On the cut surface obtained in such a manner, a Vickers hardness is measured.
  • the Vickers hardness is measured in compliance with the test method of the Vickers hardness test according to JIS Z 2244 in Japanese Industrial Standards (JIS).
  • JIS Z 2244 Japanese Industrial Standards
  • JIS Z 2244 Japanese Industrial Standards
  • an indenter is pressed into a test specimen to form an indentation, and a diagonal length of the indentation is measured.
  • a plurality of indentations are formed on the cut surface for the measurement.
  • a distance between the centers of adjacent two indentations is set at 3d or longer (d is the value of a longer one of the diagonal lengths of the indentations), distances from the centers of the indentations to the edges of the test specimen (the cut surface of the tubular part) are set at 2.5d or longer.
  • the tubular part is made of a light metal (including aluminum, an aluminum alloy, titanium, a titanium alloy, magnesium, and a magnesium alloy)
  • the distance between the centers of adjacent two indentations is set at 6d or longer, and the distances from the centers of the indentations to the edges of the test specimen are set at 3d or longer.
  • Vickers hardnesses are measured at five points lying in a straight line at regular intervals in the thickness direction. Then, from the measured values at the five points, the minimum value Bmin and the maximum value Bmax of the Vickers hardnesses are determined, and the aforementioned variation S is calculated. Also in each of the aforementioned second and third positions, Vickers hardnesses are measured in the same manner, and the aforementioned variations S is calculated. Then, by averaging the obtained three variations S, the average value of the variations S in the circumferential direction is obtained.
  • the formed metal item according to the present invention is available for various applications.
  • applications of the formed metal item include components (suspension components, bodies, structural materials, etc.) of various kinds of vehicles (automobiles, railway vehicles, and the other kinds of vehicles), components of various kinds of machines, electronic devices, electrical appliances, components of various kinds of transport aircraft (vessels, aircraft), and the other components.
  • a producing device is a producing device to produce a formed metal item that includes a tubular part with a slit.
  • This producing device is available for the producing method according to the present invention. With this producing device, it is possible to produce the formed metal item according to the present invention.
  • This producing device is a pressing device from another viewpoint, and to a configuration about which description is not made below, the configuration of a well-known pressing device may be applicable. As to matters about this producing device that have already described in another part of the description, the redundant description thereof may be omitted.
  • the matters described about the producing device according to the present invention are applicable to the producing method, the formed metal item, and the die assembly according to the present invention.
  • the producing device includes a die assembly and a movement mechanism for moving the die assembly.
  • the die assembly includes a first die and a second die.
  • the first die includes a protruding part for forming a slit.
  • the first and second dies include first and second pressing surfaces, respectively, which are configured to deform a U-shaped part having a U-shaped cross section to form a cylindrical-shape portion with a gap serving as a slit.
  • the die assembly has a configuration to press the outer peripheral surface of the cylindrical-shape portion so that the cross-section peripheral length LT of the cylindrical-shape portion is made short.
  • the producing device (a) includes the aforementioned die assembly (a).
  • the die assembly (a) has the following configurations (a-1), (a-2), and (a-3).
  • a movement mechanism of the producing device (a) includes a first movement mechanism and a second movement mechanism.
  • the first movement mechanism is a movement mechanism to bring the first die and the second die close to each other while a plurality of die members are separated. Normally, the first movement mechanism brings the first die and the second die close to each other until the first die and the second die come into contact with each other, with the plurality of die members separated.
  • the second movement mechanism is a movement mechanism to bring the separated plurality of die members close to each other.
  • the first movement mechanism corresponds to the aforementioned step (ii-1) of the example (A).
  • the second movement mechanism corresponds to the step (ii-2) of the example (A).
  • the first die of the die assembly (a) may be separable into a first die member and a second die member.
  • the protruding part for forming the slit may be constituted by a first protruding part included in the first die member and a second protruding part included in the second die member.
  • the producing device (b) includes the aforementioned die assembly (b).
  • the die assembly (b) has the following configurations (b-1), (b-2), and (b-3).
  • a movement mechanism of the producing device (b) includes a first movement mechanism and a second movement mechanism.
  • the first movement mechanism is a movement mechanism to bring the first die and the second die close to each other. Normally, the first movement mechanism brings the first die and the second die close to each other until the first die and the second die come into contact with each other, while the pressing surface of the movable part is not projecting from the pressing surface of the body part.
  • the second movement mechanism is a movement mechanism to move the movable part so that the pressing surface of the movable part projects from the pressing surface of the body part.
  • the first movement mechanism corresponds to the aforementioned step (ii-1) of the example (B).
  • the second movement mechanism corresponds to the step (ii-2) of the example (B).
  • the configurations of the movement mechanisms of the producing devices (a) and (b) have no special limitation, and use may be made of a well-known movement mechanism used in a pressing device of a double acting type.
  • the movement mechanisms of the producing devices (a) and (b) may be each configured by combining an expansion/contraction mechanism and a cam.
  • the expansion/contraction mechanism include a gas cylinder, a hydraulic cylinder, a spring, and other mechanisms.
  • a producing device for executing the aforementioned step (ii) of the example (C) which is not in accordance with the present invention has no special limitation except for using the die assembly (c).
  • the step (ii) of the example (C) which is not in accordance with the present invention can be executed with a typical pressing device.
  • a die assembly according to the present invention is a die assembly for producing a formed metal item that includes a tubular part with a slit.
  • This die assembly is available in the producing device according to the present invention. Furthermore, this die assembly is available in the producing method according to the present invention, specifically in the step (ii) of the producing method according to the present invention.
  • the formed metal item according to the present invention can be produced.
  • the redundant description thereof may be omitted.
  • the matters described about the die assembly according to the present invention are applicable to the producing method, the formed metal item, and the producing device according to the present invention.
  • the die assembly according to the present invention includes a first die that includes a protruding part for forming a slit, and a second die.
  • the first and second dies include first and second pressing surfaces, respectively, which are configured to deform a U-shaped part having a U-shaped cross section in such a manner that two end parts of the U-shaped part clamp the protruding part to form a cylindrical-shape portion with a gap serving as a slit.
  • the second pressing surface has a semi-cylinder shape
  • the first pressing surface has a semi-cylinder shape except for the protruding part.
  • the die assembly according to the present invention has a configuration to press the outer peripheral surface of the cylindrical-shape portion while the two end parts are clamping the protruding part so that the cross-section peripheral length of the cylindrical-shape portion is made short. From another viewpoint, the die assembly according to the present invention has a configuration to compress the cylindrical-shape portion in the circumferential direction. Examples of the die assembly of the present invention include the aforementioned die assembly (a) and die assembly (b).
  • the first die including the protruding part as an upper die
  • use may be made of the second die as a lower die. Therefore, in the present specification, the first die may be alternatively referred to as the upper die, and the second die may be alternatively referred to as the lower die. In addition, the first die may be alternatively referred to as the lower die, and the second die may be alternatively referred to as the upper die.
  • the protruding part has a shape that allows a slit to be formed.
  • the protruding part is a plate-shaped salient part and provided at a position in an uppermost part of the semicircular pressing surface of the upper die.
  • the protruding part is provided in a central portion of the cross section of the pressing surface of the upper die (the cross section in the circumferential direction).
  • the protruding part need not be in the central portion and may be at a position shifted from the center.
  • the protruding part may be at a position shifted from the central portion.
  • the position of the protruding part in the circumferential direction may be changed along the axis direction.
  • the width of the protruding part may be changed along the axis direction.
  • the width of the slit may be set at t or larger and (Din - 2t) or smaller.
  • a width of the slit smaller than t may result in a sufficient strength of the protruding part of the die assembly.
  • a width of the slit larger than (Din-2t) may decrease the advantageous effects of the invention.
  • the width of the protruding part is selected in accordance with the width of the slit (the gap of the butted part).
  • the width of the protruding part is preferably set within ⁇ 10% of the width of the slit.
  • the die assembly (a) at least one die selected from the first die and the second die is separable into a plurality of die members.
  • the number of the die members is large, there is the risk that the U-shaped part is likely to be clamped between adjacent die members in the forming.
  • the structures of the die assembly and a device using the die assembly become complex. Therefore, in a preferable example of the case where the first die is divided into a plurality of die members, the first die is divided into two die members.
  • the second die is divided into two die members.
  • the position of the separation has no special limitation.
  • the protruding part may be constituted by a first protruding part included in the first die member and a second protruding part included in the second die member. That is, the first die may be divided at the protruding part.
  • the die assembly (a) by moving the plurality of die members individually, it is possible to perform a fine adjustment of the cross-section peripheral length LH of the tubular part easily and to reduce variations in compressive stress acting on the tubular part. Consequently, with the die assembly (a), it is possible to suppress the spring back effectively, with the result that the slit can be formed with precision.
  • At least one die selected from the first die and the second die includes the body part and the movable part that is movable relative to the body part.
  • only the first die may include the body part and the movable part, or only the second die may include the body part and the movable part.
  • both of the first and second dies may each include the body part and the movable part.
  • the area of the pressing surface of the movable part can be increased, and as a result, at the time when the cylindrical-shape portion is pressed and compressed in the circumferential direction, the press can be performed stably.
  • the positions at which the movable parts are disposed have no special limitation as long as the positions allow the adjustment of the cross-section peripheral length of the tubular part by the movement of the movable part.
  • the movable parts may be disposed at positions corresponding to a top part and a bottom part of the tubular part or may be disposed at positions corresponding to two side parts of the tubular part.
  • the movable parts are preferably disposed at two positions that are opposed to each other across the center of the tubular part.
  • the movable parts are disposed at least in a zone where step (ii) of the example (B) is executed.
  • the movable parts may be disposed over the overall length of the die assembly or may be disposed over only in part of the die assembly.
  • the number of movable parts may be one or more. In the case where the number of movable parts is more than one, the cross-section peripheral length of the tubular part is easy to adjust finely in comparison with the case where the number of movable parts is one.
  • the number of movable parts may be one or more. In the case where the number of movable parts is more than one, the movable parts may be disposed at both of a position corresponding to the top part (or the bottom part) of the cylindrical-shape portion and positions corresponding to the side parts of the cylindrical-shape portion.
  • the movable part(s) can be moved by a cylinder, a cam mechanism, or the like so as to move relative to the body part.
  • the protruding part for forming a slit may be replaceable.
  • the protruding part may be replaceable.
  • the protruding part easily wears.
  • the lifetime of the die assembly can be extended.
  • the width of the slit becomes easy to adjust.
  • the entire die assembly needs to be changed whenever the physical properties or the thickness of the metal plate varies.
  • the width of the slit becomes easy to adjust without changing the entire die assembly.
  • the shape of the die assembly is designed as appropriate in conformity with the shape and the like of an intended tubular part.
  • the cross-sectional shape in a circumferential direction of the pressing surface of a die assembly may be a vertically asymmetric shape or may be a horizontally asymmetric shape.
  • the cross-sectional shape in the circumferential direction of the pressing surface of the die assembly may be constant in an axis direction or may change in the axis direction.
  • the pressing surface of the die assembly may be straight in the axis direction or may be bent relative to the axis direction.
  • the first die and the second die each may be of a single acting type.
  • the first die and the second die each may be of a double acting type as necessary.
  • at least one selected from the first and second dies is of the double acting type.
  • the use of a die assembly of the double acting type allows the cross-section peripheral length of the cylindrical-shape portion to be adjusted finely and allows variations in compressive stress acting on the cylindrical-shape portion to be reduced. Therefore, it is possible to suppress in particular spring back effectively and to increase in particular the precision of the shape of the formed metal item.
  • a producing device including the die assembly includes a mechanism used in a pressing device of the double acting type or a mechanism including a cylinder, a cam, or the like.
  • the die assembly In the case where the material or the thickness of a metal plate varies, the amount of spring back also varies accordingly. Therefore, in a forming method using a conventional die assembly, when the material or the thickness of a metal plate varies, the die assembly needs to be changed accordingly.
  • the die assembly according to the present invention it is possible to change the compressibility of a tubular part without changing the die assembly. For example, with the die assembly (a), the compressibility of the tubular part can be changed by changing distances between a plurality of die members. In addition, with the die assembly (b), the compressibility of the tubular part can be changed by changing the amounts of movement of the movable parts.
  • the die assembly according to the present invention even in the case where the material or the thickness of a metal plate varies, it is possible to control the breadth of the slit without changing the die assembly. Consequently, the die assembly according to the present invention is suitable for volume production of the formed metal item according to the present invention.
  • the die assembly according to the present invention it is possible to reduce variations in hardness distribution in the thickness direction and variations in hardness distribution in the circumferential direction, of the tubular part. Therefore, by the use of the die assembly according to the present invention, it is possible to produce a formed metal item having a high fatigue strength.
  • the formed metal item according to the present invention includes a tubular part with a slit.
  • FIG. 1 schematically illustrates a cross section in a direction orthogonal to the axis direction of the tubular part (a cross section in a circumferential direction).
  • a formed metal item 1 includes a tubular part 1e that is formed with a slit 3 and is typically constituted by only the tubular part 1e. In the slit 3, two end parts E1 and E2 are butted against each another. From another viewpoint, the formed metal item 1 is a substantially-closed-cross-sectional component (a tubular component having a substantially-closed cross section).
  • the substantially-closed cross section refers to a cross section in which a gap is present between two butted end parts of a metal plate that is formed to be tubular.
  • the substantially-closed-cross-sectional component may have the gap across the overall length of a butted part or may have the gap only in part of the butted part.
  • An angle ⁇ formed by the line OP1 and the line OP2 is preferably 30° or larger.
  • An excessively small angle ⁇ leads to little difference in cross section between the tubular part 1e and the U-shaped part, which may decrease the strength (flexural strength) of the tubular part after forming.
  • the angle ⁇ in a typical example is 150° or larger (e.g., 170° or larger).
  • the angle ⁇ is preferably 180° or smaller. An excessively large angle ⁇ leads to the risk of an unstable forming.
  • Step (i) is schematically illustrated in FIG. 2A and 2B .
  • a metal plate (blank) 1a is disposed between a die 11 and a punch 12.
  • the die assembly for U forming is configured by the die 11 and the punch 12.
  • the metal plate 1a is subjected to press forming to be formed into a U-shaped part 1b having a U-shaped cross section.
  • the U-shaped part 1b includes two end parts E1 and E2.
  • step (i) the size relation between a width W of a part to be made into a tubular part (the tubular part 1e) and the cross-section length LU of the U-shaped part 1b, of the metal plate, changes under various conditions (the shape of the tubular part, the conditions of step (i), etc.). These conditions can result in the case where the cross-section length LU is longer than the width W, the case where the cross-section length LU is shorter than the width W, and the case where both are equal to each other.
  • step (ii) it is important to form the tubular part in such a manner that the cross-section peripheral length LH of the tubular part is shorter than the cross-section length LU of the U-shaped part. Therefore, the relation between the width W and the cross-section length LU in step (i) has no special limitation.
  • FIG. 3A schematically illustrates a die assembly used in step (ii) of in the second embodiment.
  • a die assembly 20 in the second embodiment is an example of the aforementioned die assembly (a).
  • the die assembly 20 includes an upper die (first die) 21 and a lower die (second die) 22.
  • the upper die 21 includes a plate-shaped protruding part 23 for forming a slit.
  • the upper die 21 includes a first upper die (first die member) 21a and a second upper die (second die member) 21b that are separable in a horizontal direction.
  • the protruding part 23 is configured by a first protruding part 23a included in the first upper die 21a and a second protruding part 23b included in the second upper die 21b.
  • the lower die 22 includes a first lower die (first die member) 22a and a second lower die (second die member) 22b that are separable in the horizontal direction.
  • the upper die 21 includes a first pressing surface 21p that is configured to press the outer peripheral surface of the U-shaped part 1b to form the cylindrical-shape portion 1d.
  • the lower die 22 includes a first pressing surface 22p that is configured to press the outer peripheral surface of the U-shaped part 1 b to form the cylindrical-shape portion 1d ( FIG. 3D ).
  • the protruding part 23 is a plate-shaped salient part, the length of which is equal to or longer than the slit 3 to be formed.
  • the cross-section peripheral length of the entire pressing surface of the die assembly 20 (the first pressing surface 21p and the second pressing surface 22p) is shorter than the cross-section length LU of the U-shaped part 1b.
  • Step (ii) in the second embodiment is the aforementioned step of the example (A) and includes step (ii-1) and step (ii-2).
  • step (ii) the tubular part 1e with a slit can be formed from the U-shaped part 1b.
  • step (ii) of the second embodiment first, the U-shaped part 1b is disposed in the die assembly 20 as illustrated in FIG. 3B .
  • the U-shaped part 1b is deformed using the die assembly 20, with the end part E1 and the end part E2 of the U-shaped part 1b (see FIG. 2C ) clamping the protruding part 23 (Step (ii-1)).
  • the upper die 21 and the lower die 22 are brought close to each other until both come into contact with each other, so that the outer peripheral surface of the U-shaped part 1b is pressed by the pressing surface of the die assembly 20.
  • Step (ii-1) is executed in the state where the first upper die 21a and the second upper die 21b are separated in the horizontal direction, and the first lower die 22a and the second lower die 22b are separated in the horizontal direction.
  • the upper die 21 and/or the lower die 22 is moved in the vertical direction, so that both are brought close to each other.
  • step (ii-1) the cylindrical-shape portion 1d is formed.
  • the U-shaped part 1b is deformed into a U-shaped part 1c.
  • two end parts of the U-shaped part 1c are butted against the protruding part 23 to stop, so that a gap is generated between the end parts.
  • the gap serves as the slit 3 of the tubular part 1e.
  • the end part E1 and the end part E2 face each other across the protruding part 23 (the protruding parts 23a and 23b).
  • the cross-section length of the U-shaped part 1b and the cross-section peripheral length LT of the cylindrical-shape portion 1d may be made substantially equal to each other.
  • This configuration can be implemented by adjusting the interval between the first upper die 21a and the second upper die 21b, and the interval between the first lower die 22a and the second lower die 22b.
  • Step (ii-2) by pressing the outer peripheral surface of the cylindrical-shape portion 1d while the end parts E1 and E2 of the U-shaped part 1b are clamping the protruding part 23, the cross-section peripheral length LT of the cylindrical-shape portion 1d is shortened (Step (ii-2)). Specifically, by closing the divided die assembly 20, the cross-section peripheral length LT is shortened. More specifically, the first upper die 21a and the second upper die 21b are moved in the horizontal direction to come close to each other, and the first lower die 22a and the second lower die 22b are moved in the horizontal direction to come close to each other. In the example illustrated in FIG.
  • the first upper die 21a and the second upper die 21b come into contact with each other, and the first lower die 22a and the second lower die 22b are brought close to each other until they come into contact with each other. That is, in the example illustrated in FIG. 3E , the pressing surface of the die assembly 20 in a completely closed state corresponds to the outer peripheral surface of the tubular part 1e.
  • the cross-section peripheral length LT of the cylindrical-shape portion 1d in step (ii-2) it is possible to make the cross-section peripheral length LH of the tubular part 1e shorter than the cross-section length LU of the U-shaped part 1b. In this manner, a tubular part 1e (formed metal item) illustrated in FIG. 3F is obtained.
  • the butted part 2 of the tubular part 1e is formed with the slit 3.
  • FIG. 3E illustrates the case where the die assembly is completely closed in a final phase of the forming.
  • the die assembly need not be completely closed in the final phase of the forming.
  • the aforementioned compressibility C can be changed.
  • the cross-section peripheral length LH of the tubular part 1e is made shorter than the cross-section length LU of the U-shaped part 1b. That is, in the producing method according to the present invention, the cylindrical-shape portion 1d is compressed in the circumferential direction, and the tubular part 1e is thereby obtained. As a result, in the tubular part 1e, compressive stress acts on both of the inner circumferential side and the outer circumference side. Consequently, the spring back is inhibited, and the slit 3 can be formed with precision.
  • the tubular part 1e is formed. Therefore, in the tubular part 1e, compressive stress acts on both of the inner circumferential side and the outer circumference side. Furthermore, in the tubular part 1e, it is possible to reduce variations in the compressive stress in the circumferential direction. As a result, it is possible to reduce variations in hardness distribution in the thickness direction and to reduce variations in hardness distribution in the circumferential direction, of the tubular part 1e. Consequently, according to the present invention, it is possible to obtain a tubular part having a high fatigue strength.
  • the cylindrical-shape portion 1d is compressed by moving all of the die members surrounding the cylindrical-shape portion 1d relatively. Therefore, by the producing method and the die assembly in the second embodiment, it is possible to compress the cylindrical-shape portion 1d uniformly in the circumferential direction. Consequently, the spring back can be inhibited effectively, and it is possible to increase the shape precision of the tubular part even more.
  • step (i) is the same as step (i) described in the second embodiment, and thus the redundant description thereof will be omitted.
  • FIG. 4A schematically illustrates a die assembly used in step (ii) in the third embodiment.
  • a die assembly 30 in the third embodiment is an example of the aforementioned die assembly (b).
  • the die assembly 30 includes an upper die (first die) 31 and a lower die (second die) 32.
  • the upper die 31 includes a plate-shaped protruding part 33 for forming the slit 3.
  • the upper die 31 includes a body part 31a and a movable part 31b that is movable relatively to the body part 31a.
  • the movable part 31b is disposed in a top part of a pressing surface 31ap of the body part 31a and includes the protruding part 33.
  • the lower die 32 includes a body part 32a and a movable part 32b that is movable relatively to body part 32a.
  • the movable part 32b is disposed in a bottom part of a pressing surface 32ap of the body part 32a.
  • both of the movable parts 31b and 32b are movable in a pressing direction (the vertical direction).
  • the movable part 31b can be moved in the pressing direction together with the body part 31a.
  • the movable part 32b can be moved in the pressing direction together with the body part 32a.
  • the body part and the movable part can be moved basically together in the pressing direction.
  • end faces of the movable parts basically constitute parts of the pressing surface, and rolls or the like are not disposed therein.
  • the movable parts are basically movable, with first and second body parts lying at a final position in the forming (a dead point).
  • the body part 31a and the body part 32a include the pressing surfaces 31ap and 32ap, respectively, the pressing surfaces 31ap and 32ap being configured to press the outer peripheral surface of the U-shaped part 1b to form the cylindrical-shape portion 1d.
  • the movable parts 31b and 32b include pressing surfaces 31bp and 32bp, respectively, the pressing surfaces 31bp and 32bp being configured to press the outer peripheral surface of the U-shaped part 1b.
  • the pressing surface 31ap and the pressing surface 31bp constitute the pressing surface 31p of the upper die 31.
  • the pressing surface 32ap and the pressing surface 32bp constitute the pressing surface 32p of the lower die 32.
  • the cross-section peripheral length of the entire pressing surface is longer than the cross-section peripheral length LH of the tubular part 1e.
  • the cross-section peripheral length of the entire pressing surface may be substantially equal to the cross-section length LU of the U-shaped part 1b.
  • Step (ii) in the third embodiment is the aforementioned step of the example (B) and includes step (ii-1) and step (ii-2).
  • step (ii) the tubular part 1e with a slit can be formed from the U-shaped part 1b.
  • step (ii) of the third embodiment first, the U-shaped part 1b is disposed in the die assembly 20 as illustrated in FIG. 4B .
  • the U-shaped part 1b is deformed using the die assembly 30, while the end part E1 and the end part E2 of the U-shaped part 1b (see FIG. 2C ) are clamping the protruding part 33 (Step (ii-1)).
  • the upper die 31 and the lower die 32 are brought close to each other until both come into contact with each other, so that the outer peripheral surface of the U-shaped part 1b is pressed by the pressing surface of the die assembly 30.
  • Step (ii-1) is executed with the pressing surfaces 31bp and 32bp of the movable parts 31b and 32b not projecting from the pressing surfaces 31p and 32p of the body part.
  • step (ii-1) the cylindrical-shape portion 1d is formed. That is, in the example illustrated in FIG. 4D , the pressing surfaces 31p and 32p correspond to the outer peripheral surface of the cylindrical-shape portion 1d.
  • the U-shaped part 1b is deformed into a U-shaped part 1c. At this point, two end parts of the U-shaped part 1c are butted against the protruding part 33 to stop, so that a gap is generated between the end parts. The gap serves as the slit 3 of the tubular part 1e.
  • the end part E1 and the end part E2 face each other across the protruding part 33.
  • the cross-section peripheral length of the entire pressing surface of the die assembly 30 may be made substantially equal to the cross-section length LU of the U-shaped part 1b.
  • the cross-section peripheral length of the entire pressing surface of the die assembly 30 may be made substantially equal to the cross-section length LU of the U-shaped part 1b.
  • Step (ii-2) by pressing the outer peripheral surface of the cylindrical-shape portion 1d while the end parts E1 and E2 of the U-shaped part 1b are clamping the protruding part 33, the cross-section peripheral length LT of the cylindrical-shape portion 1d is shortened (Step (ii-2)). Specifically, by causing the pressing surfaces of the movable parts 31b and 32b to project from the pressing surfaces of the body parts 31a and 32a, the outer peripheral surface of the cylindrical-shape portion 1d is pressed. In the third embodiment, the slit 3 and the positions facing the slit 3, of the cylindrical-shape portion 1d, are pressed vertically.
  • the cross-section peripheral length LH of the tubular part 1e is made shorter than the cross-section length LU of the U-shaped part 1b. In this manner, a tubular part 1e (formed metal item) illustrated in FIG. 4F is obtained.
  • the butted part 2 of the tubular part 1e is formed with the slit 3.
  • the tubular part 1e is formed. Therefore, as described in the second embodiment, the slit 3 can be formed with precision.
  • the producing method in the third embodiment it is possible to change the aforementioned compressibility easily by changing the amount of movement of the movable parts. Therefore, even in the case where the thickness or the physical properties of the metal plate 1a vary, it is in some cases possible to produce a desired tubular part 1e without changing the die assembly.
  • the protruding part 33 can be replaced by replacing the movable part 31b, which makes it easy to replace the protruding part 33.
  • the cylindrical-shape portion 1d is compressed in the state where a contact area between the cylindrical-shape portion 1d and the die assembly 30 is small. In this case, compressive force exerted in the circumferential direction by the movable parts is likely to be exerted on the entire cylindrical-shape portion 1d. Therefore, by the producing method and the die assembly in the third embodiment, it is possible to compress the cylindrical-shape portion 1d more uniformly in the circumferential direction.
  • This producing device includes a first support table 141, a second support table 142, expansion/contraction mechanisms 141a, and expansion/contraction mechanisms 142a.
  • the expansion/contraction mechanisms 141a and the movable part 31b are disposed.
  • the expansion/contraction mechanisms 141a are expandable in the pressing direction and are configured to press the body part 31a.
  • the expansion/contraction mechanisms 142a and the movable part 32b are disposed.
  • the expansion/contraction mechanisms 142a are expandable in the pressing direction and are configured to support the body part 32a.
  • the expansion/contraction mechanisms 141a and 142a have no special limitation, and each may be a gas cylinder, a hydraulic cylinder, a spring, or other mechanisms.
  • step (ii) of the third embodiment first, the U-shaped part 1b is disposed in the die assembly 30 as illustrated in FIG. 14A .
  • step (ii-1) is thereby performed, and the cylindrical-shape portion 1d is obtained.
  • step (ii-1) is thereby performed, and the cylindrical-shape portion 1d is obtained.
  • step (ii-1) is thereby performed, and the cylindrical-shape portion 1d is obtained.
  • FIG. 14D by causing the expansion/contraction mechanisms to contract, the first support table 141 and the second support table 142 are brought closer to each other.
  • step (ii-2) is performed.
  • a mechanism to bring the first support table 141 and the second support table 142 close to each other correspond to the aforementioned the first movement mechanism of the producing device (b).
  • a mechanism to bring the first support table 141 and the second support table 142 close to each other, and the expansion/contraction mechanism 141a and the expansion/contraction mechanism 142a in the expanding/contracting state correspond to the second movement mechanism.
  • the single constituting member may serve as the first movement mechanism and the second movement mechanism.
  • step (i) is the same as step (i) described in the second embodiment, and thus the redundant description thereof will be omitted.
  • FIG. 5A schematically illustrates a die assembly used in step (ii) in the fourth embodiment.
  • a die assembly 30 in the fourth embodiment is an example of the aforementioned die assembly (b).
  • the die assembly 30 includes an upper die (first die) 31 and a lower die (second die) 32.
  • the upper die 31 includes a plate-shaped protruding part 33 for forming the slit 3.
  • the upper die 31 includes a body part 31a and two movable parts 31b that are movable relative to the body part 31a.
  • the movable parts 31b are disposed in the lowermost part of the pressing surface of the body part 31a.
  • the lower die 32 includes a body part 32a and two movable parts 32b that are movable relative to body part 32a.
  • the movable parts 32b are disposed in the uppermost part of the pressing surface of the body part 32a.
  • both of the movable parts 32a and 32b are movable in the horizontal direction.
  • the movable part 31b can be moved in the vertical direction (pressing direction) together with the body part 31a.
  • the movable part 32b can be moved in the vertical direction together with the body part 32a.
  • the body part 31a and the body part 32a include the pressing surfaces 31ap and 32ap, respectively, the pressing surfaces 31ap and 32ap being configured to press the outer peripheral surface of the U-shaped part 1b to form the cylindrical-shape portion 1d.
  • the movable parts 31b and 32b include pressing surfaces 31bp and 32bp, respectively, the pressing surfaces 31bp and 32bp being configured to press the outer peripheral surface of the U-shaped part 1b.
  • the cross-section peripheral length of the entire pressing surface is longer than the cross-section peripheral length LH of the tubular part 1c.
  • the cross-section peripheral length of the entire pressing surface may be substantially equal to the cross-section length LU of the U-shaped part 1b.
  • Step (ii) in the fourth embodiment is the aforementioned step of the example (B) and includes step (ii-1) and step (ii-2).
  • step (ii) the tubular part 1e with a slit can be formed from the U-shaped part 1b.
  • step (ii) of the fourth embodiment first, the U-shaped part 1b is disposed in the die assembly 30 as illustrated in FIG. 5B .
  • the U-shaped part 1b is deformed using the die assembly 30, while the end part El and the end part E2 of the U-shaped part 1b (see FIG. 2C ) are clamping the protruding part 33 (Step (ii-1)).
  • the upper die 31 and the lower die 32 are brought close to each other until both come into contact with each other, so that the outer peripheral surface of the U-shaped part 1b is pressed by the pressing surface of the die assembly 30.
  • Step (ii-1) is executed with the pressing surfaces 31bp and 32bp of the movable parts not projecting from the pressing surfaces 31ap and 32ap of the body part.
  • step (ii-1) the cylindrical-shape portion 1d is formed.
  • the U-shaped part 1b is deformed into a U-shaped part 1c.
  • two end parts of the U-shaped part 1c are butted against the protruding part 33 to stop, so that a gap is generated between the end parts.
  • the gap serves as the slit 3 of the tubular part 1e.
  • the end part E1 and the end part E2 face each other across the protruding part 33.
  • the cross-section peripheral length of the entire pressing surface of the die assembly 30 may be made substantially equal to the cross-section length LU of the U-shaped part 1b.
  • the cross-section peripheral length of the entire pressing surface of the die assembly 30 may be made substantially equal to the cross-section length LU of the U-shaped part 1b.
  • Step (ii-2) by pressing the outer peripheral surface of the cylindrical-shape portion 1d while the end parts E1 and E2 of the U-shaped part 1b are clamping the protruding part 33, the cross-section peripheral length LT of the cylindrical-shape portion 1d is shortened (Step (ii-2)). Specifically, by causing the pressing surfaces 31bp and 32bp of the movable parts 31b and 32b to project from the pressing surfaces 31ap and 32ap of the body parts 31a and 32b, the outer peripheral surface of the cylindrical-shape portion 1d is pressed. In the fourth embodiment, the side faces of the cylindrical-shape portion 1d are pressed from right and left.
  • the cross-section peripheral length LH of the tubular part 1e is made shorter than the cross-section length LU of the U-shaped part 1b. In this manner, a tubular part 1e (formed metal item) illustrated in FIG. 5F is obtained.
  • the butted part 2 of the tubular part 1e is formed with the slit 3.
  • the tubular part 1e is formed. Therefore, as described in the second and third embodiments, the slit 3 can be formed with precision.
  • This producing device includes a first support table 151, two expansion/contraction mechanisms 141a, two shafts 153, and two cam units 154.
  • the expansion/contraction mechanisms 141a and the shafts 153 are disposed on the first support table 151.
  • the expansion/contraction mechanisms 141a are expandable in the pressing direction and are configured to press the body part 31a.
  • step (ii) of the fourth embodiment first, the U-shaped part 1b is disposed in the die assembly 30 as illustrated in FIG. 15A .
  • the first support table 151 is pressed down.
  • the aforementioned step (ii-1) is thereby performed, and the cylindrical-shape portion 1d is obtained.
  • the first support table 151 is further pressed down.
  • the two cam units 154 are moved by the two shafts 153, and the movable parts 31b and 32b are moved by the cam units 154.
  • step (ii-2) is performed.
  • a mechanism to move the first support table 151 downward (not illustrated) and the expansion/contraction mechanisms 141a not in an expanding/contracting state correspond to the aforementioned the first movement mechanism of the producing device (b).
  • a mechanism to move the first support table 151 downward, the shafts 153, and the cam units 154 constitute the second movement mechanism.
  • These movement mechanisms may be implemented by using movement mechanisms of a well-known pressing device with the movement mechanisms adapted to the producing device according to the present invention.
  • step (i) is the same as step (i) described in the second embodiment, and thus the redundant description thereof will be omitted.
  • FIG. 6A schematically illustrates a die assembly used in step (ii) in the fifth embodiment.
  • a die assembly 20 in the fifth embodiment includes an upper die (first die) 21 and a lower die (second die) 22.
  • the upper die 21 includes a plate-shaped protruding part 23 for forming a slit 3.
  • the first upper die 21 and the second lower die 22 include pressing surfaces 21p and 22p, respectively, the pressing surfaces 21p and 22p being configured to press the outer peripheral surface of the U-shaped part 1b to form the cylindrical-shape portion 1d.
  • the cross-section peripheral length of the entire pressing surface is shorter than the cross-section length LU of the U-shaped part 1b.
  • Step (ii) in the fifth embodiment is the aforementioned step of the example (C).
  • step (ii) of the fifth embodiment first, the U-shaped part 1b is disposed in the die assembly 20 as illustrated in FIG. 6B .
  • the cylindrical-shape portion 1d is formed by deforming the U-shaped part 1b using the die assembly 20 in such a manner that the end part E1 and the end part E2 of the U-shaped part 1b clamp the protruding part 23.
  • the upper die 21 and the lower die 22 are brought close to each other, so that the outer peripheral surface of the U-shaped part 1b is pressed by the pressing surface of the die assembly 20.
  • the U-shaped part 1b is deformed into a U-shaped part 1c.
  • two end parts of the U-shaped part 1c are butted against the protruding part 23 to stop, so that a gap is generated between the end parts.
  • the gap serves as the slit 3 of the tubular part 1e.
  • FIG. 6D illustrates an example of the state where the cross-section peripheral length LT of the cylindrical-shape portion 1d is substantially equal to cross-section length LU of the U-shaped part 1b. Since the cross-section peripheral length of the pressing surface of the die assembly 20 is shorter than the cross-section length LU of the U-shaped part 1b, the upper die 21 and the lower die 22 are not in contact with each other in the stage illustrated in FIG. 6D . That is, in the stage illustrated in FIG. 6D , the die assembly 20 is not closed.
  • the upper die 21 and the lower die 22 are brought closer to each other from the stage FIG. 6D , so that die assembly 20 is closed as illustrated in FIG. 6E .
  • the upper die 21 and the lower die 22 are brought into contact with each other.
  • the outer peripheral surface of the cylindrical-shape portion 1d is pressed by the pressing surface of the die assembly 20 while the two end part E1 and end part E2 are clamping the protruding part 23.
  • a tubular part 1e that includes a slit 3 in its butted part 2 illustrated in FIG. 6F is thereby formed.
  • the cross-section peripheral length of the pressing surface of the die assembly 20 is shorter than the cross-section length LU of the U-shaped part 1b.
  • the cross-section peripheral length LH of the tubular part 1e is made shorter than the cross-section length LU of the U-shaped part 1b. That is, in the step illustrated in FIG. 6E , the cylindrical-shape portion 1d is compressed in the circumferential direction to be made into the tubular part 1e.
  • the forming can be terminated before the die assembly 20 is completely closed.
  • the upper die 21 and the second lower die 22 are brought close to each other, it is possible to adjust the compressibility of the tubular part 1e.
  • the tubular part 1e is formed. Therefore, as described in the second embodiment, the slit 3 can be formed with precision.
  • FIG. 7 illustrates an example of a die assembly that includes a replaceable protruding part.
  • a die assembly 20 illustrated in FIG. 7 includes an upper die (first die) 21 and a lower die (second die) 22.
  • the upper die 21 includes a part 24 that includes a protruding part 23.
  • the part 24 is inserted into a hole 25 of the upper die 21 and is made replaceable.
  • the protruding part 23 is a part with which the two end parts (end parts E1 and E2) of the U-shaped part are to come into contact and is likely to be abraded or deformed. Therefore, the protruding part 23 is preferably made replaceable. Furthermore, by replacing the protruding part 23, the aforementioned effect is obtained.
  • the present invention provides a method for producing a substantially-closed-cross-sectional component that includes a gap in its butted part.
  • the producing method in accordance with this viewpoint is referred to as a producing method (S).
  • the producing method (S) includes a first step and a second step.
  • a metal plate is formed to have a U shape, whereby a U-formed item is obtained.
  • This U-formed item corresponds to a formed item that includes a U-shaped part formed by the aforementioned step (i).
  • the U-formed item is formed to have a substantially-closed cross section, using a die assembly, and the cross-section peripheral length of the substantially-closed-cross-sectional component is made shorter than the cross-section peripheral length of the U-formed item.
  • the die assembly in use includes a protruding part corresponding to the butted part of the substantially-closed-cross-sectional component and includes a mechanism that is capable of adjusting the cross-section peripheral length of the substantially-closed-cross-sectional component. Examples of this die assembly include the aforementioned die assemblies (a), (b), and (c).
  • the first step and the second step correspond to the aforementioned steps (i) and (ii), respectively.
  • the substantially-closed-cross-sectional component including the gap corresponds to the aforementioned formed metal item that includes a tubular part with a slit.
  • the substantially-closed-cross-sectional component refers to a component having a substantially-closed cross section.
  • the substantially-closed cross section refers to a cross section in which a gap is present between two butted end parts of a metal plate that is formed to be tubular.
  • the substantially-closed-cross-sectional component may have the gap across the overall length of a butted part or may have the gap only in part of the butted part.
  • the cross-section peripheral length of the die assembly may be shorter than the cross-section peripheral length of the U-formed item.
  • the cross-section peripheral length of a die assembly refers to the cross-section peripheral length of the die assembly when the die assembly is completely closed.
  • the die assembly may include an upper die that includes the protruding part, and a lower die, and at least one of the upper die and the lower die may include a body part and a movable part.
  • the die assembly having this configuration corresponds to the aforementioned die assembly (b).
  • the present invention provides a die assembly for forming a U-formed item to have a substantially-closed cross section so as to produce a substantially-closed-cross-sectional component that includes a gap in its butted part.
  • this die assembly is referred to as a die assembly (T1).
  • the die assembly (T1) includes an upper die and a lower die that include a protruding part corresponding to the butted part of the substantially-closed-cross-sectional component.
  • the die assembly (T1) includes a mechanism that is capable of adjusting the cross-section peripheral length of the substantially-closed-cross-sectional component.
  • at least one of the upper die and the lower die is divided into a plurality of pieces.
  • the die assembly (T1) corresponds to the aforementioned die assembly (a).
  • the protruding part of the upper die may be divided.
  • An example of the die assembly having this configuration is the die assembly 20 illustrated in FIG. 3A .
  • the present invention provides another die assembly for forming a U-formed item to have a substantially-closed cross section so as to produce a substantially-closed-cross-sectional component that includes a gap in its butted part.
  • this die assembly is referred to as a die assembly (T2).
  • the die assembly (T2) includes an upper die and a lower die that include a protruding part corresponding to the butted part of the substantially-closed-cross-sectional component.
  • the die assembly (T2) includes a mechanism that is capable of adjusting the cross-section peripheral length of the substantially-closed-cross-sectional component.
  • at least one of the upper die and the lower die includes a body part and a movable part.
  • the die assembly (T2) corresponds to the aforementioned die assembly (b).
  • the protruding part may be made replaceable.
  • Example 1 a U-formed item (U-shaped part) was formed by the producing method illustrated in FIGS. 2A to 2B , and further, a tubular member (formed metal item) with a slit was fabricated by the producing method illustrated in FIGS. 3B to 3E .
  • a metal plate blade
  • TS tensile strength
  • the tubular member was made to have an outer diameter of 50 mm and a length of 200 mm.
  • the width of the protruding part of the upper die was set at 5 mm.
  • Example 2 a tubular member with a slit was fabricated using the metal plate as in Example 1 by the producing method illustrated in FIGS. 2A to 2B and FIGS. 4B to 4E .
  • the dimensions of the tubular member and of the width of the protruding part of the upper die were set as in Example 1.
  • Example 3 a U-formed item (U-shaped part) was formed using the metal plate as in Example 1 by the producing method illustrated in FIGS. 2A to 2B , and further, a tubular member with a slit was fabricated by the producing method illustrated in FIGS. 5B to 5E .
  • the dimensions of the tubular member and of the width of the protruding part of the upper die were set as in Example 1.
  • Example 4 a U-formed item (U-shaped part) was formed using the metal plate as in Example 1 by the producing method illustrated in FIGS. 2A to 2B , and further, a tubular member with a slit was fabricated by the producing method illustrated in FIGS. 6B to 6E .
  • the dimensions of the tubular member and of the width of the protruding part of the upper die were set as in Example 1.
  • U forming was performed using the metal plate as in Example 1 by the method illustrated in FIGS. 2A to 2B . Thereafter, as illustrated in FIGS. 11A to 11B , O forming was performed using a die assembly (an upper die 51 and a lower die 52) that includes no protruding part and includes a core 53. In such a manner, a tubular member 50b with a slit was fabricated. The cross-section peripheral length of the pressing surface of the die assembly when the die assembly is completely closed was made longer than the cross-section length of the U-formed item (U-shaped part).
  • Example 1 the compressibility C was set at 0.99%. In Comparative Examples 1 and 2, the compressibility C was set at about 0%.
  • Example 1 For the tubular members in Example 1, Comparative Example 1 and Comparative Example 2, strain distributions in the thickness direction in their cross sections were measured. The results of the measurement are illustrated in FIG. 12A .
  • the ordinate of FIG. 12A represents absolute value of strain.
  • the tubular member in Example 1 had a large absolute value of strain in comparison with the tubular members in Comparative Examples 1 and 2 and had a narrow strain distribution in the thickness direction.
  • FIG. 12B The results of the measurement are illustrated in FIG. 12B .
  • the ordinate of FIG. 12B represents absolute value of strain.
  • FIG. 12B it is assumed that the bottom part of the cross section of a tubular member is at 0°, and the butted part thereof is at 180°.
  • the tubular members in Examples 2 to 4 had large absolute values of strain in comparison with the tubular member in Comparative Example 2.
  • FIG. 13 is a graph illustrating relation between the average value of variations S in the circumferential direction and the rate of reduction of uniaxial compressive strength.
  • the graph illustrated in FIG. 13 is a graph obtained by assuming a plurality of round tubes in each of which the average value of variations S in the circumferential direction is a given value, and simulating the results of a uniaxial compression test conducted on the plurality of round tubes.
  • the ordinate of the graph illustrated in FIG. 13 represents the rate of reduction of uniaxial compressive strength with respect to the average value of variations S of a round tube in the circumferential direction being zero.
  • FIG. 13 illustrates two dotted lines that represent the tendencies of changes in rate of reduction of uniaxial compressive strength.
  • the rate of reduction of uniaxial compressive strength significantly increased.
  • the average value of the variations S in the circumferential direction is smaller than 0.4, the rate of reduction of uniaxial compressive strength was low.
  • the results illustrated in FIG. 13 suggest that it is important to set the average value of the variations S in the circumferential direction at less than 0.4.
  • the present invention is available to a formed metal item that includes a tubular part with a slit, and a method for producing the formed metal item. Furthermore, the present invention is available to a producing device for producing the formed item, and a die assembly used in the producing device.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Bending Of Plates, Rods, And Pipes (AREA)
  • Shaping Metal By Deep-Drawing, Or The Like (AREA)
  • Mounting, Exchange, And Manufacturing Of Dies (AREA)
EP16755009.4A 2015-02-25 2016-02-25 Formed metal item including tubular part with slit, method for producing the same, and producing device and die assembly used in method for producing the same Active EP3263240B1 (en)

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PCT/JP2016/001012 WO2016136259A1 (ja) 2015-02-25 2016-02-25 スリットを有する管状部を含む金属成形品およびその製造方法、ならびにそれに用いられる製造装置および金型

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CA2975861C (en) 2019-10-01
CN107427879A (zh) 2017-12-01
KR101983929B1 (ko) 2019-05-29
US20180021829A1 (en) 2018-01-25
JP6531818B2 (ja) 2019-06-19
JPWO2016136259A1 (ja) 2017-11-02
CA2975861A1 (en) 2016-09-01
EP3263240A4 (en) 2019-01-23
RU2017133119A3 (ja) 2019-03-25
EP3263240A1 (en) 2018-01-03
KR20170119700A (ko) 2017-10-27
BR112017016143A2 (ja) 2018-04-17
RU2017133119A (ru) 2019-03-25
WO2016136259A1 (ja) 2016-09-01
RU2683673C2 (ru) 2019-04-01
MX2017010764A (es) 2017-11-28

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