The present invention relates to a press-formed product having an external shape that curves in an L shape along a longitudinal direction in a planar view. More specifically, the present invention relates to a press-forming apparatus for producing a press-formed product having a cross-sectional form that is a hat shape, a method for producing a press-formed product using the forming apparatus, and a press-formed product.
The body of an automobile includes various structural members (for example, a front pillar lower outer reinforcement, a front pillar inner, a side sill outer reinforcement rear, a side sill inner and a rear side member). Press-formed products are frequently used as the structural members. In many cases, the cross-sectional form of a press-formed product that is used as a structural member is a hat shape or a groove shape.
The above described type of press-fainted product having a hat-shaped cross section is formed by press working using a punch and die. At the time of press-forming, a blank holder is sometimes used to hold the edge of a metal plate (for example, a steel plate) that is a starting material. Press forming that uses a blank holder is also referred to as “drawing”. Further, in press-forming (drawing), a pad is sometimes used together with a blank holder.
A press-forming apparatus 20 is equipped with an upper die 40 and a lower die 30. The upper die 40 includes a die 50 and a pad 41. The lower die 30 includes a punch 31, and blank holders 32 and 33 that are adjacent to two side portions of the punch 31, respectively.
The punch 31 has a die impression in which the shape of the press-formed product is reflected. In other words, as shown in
The die 50 has a die impression in which the shape of the press-formed product is reflected. In other words, the die 50 has guide faces 50c and 50d that have a shape that corresponds to a flange portion of the press-formed product, respectively. In addition, the die 50 has inner side faces 50a and 50b that have a shape that corresponds to a vertical wall portion of the press-formed product. The pad 41 constitutes one part of the die 50, and has an end face that has a shape that corresponds to the top plate portion of the press-formed product.
The pad 41 is mounted to the die 50 via a pad pressurizing mechanism (for example, a spring, rubber, a gas cylinder or a hydraulic cylinder) 42. By this means, the pad 41 is slidable in a pressing direction. Therefore the pad 41 is individually slidable with respect to the die 50. The end face of the pad 41 faces the end face 31a of the punch 31. Note that, in some cases the pad 41 is mounted to a die or a fixing jig or the like that is integrated with a ram (not illustrated in the drawings) of the press-forming apparatus and makes the same movement as the ram.
The blank holders 32 and 33 are slidably supported in a pressing direction by blank holder pressurizing mechanisms (for example, a spring, rubber, a hydraulic cylinder or a gas cylinder) 36 and 37, respectively. In this case, the term “pressing direction” refers to a direction in which the punch 31 and the die 50 relatively move at the time of press-forming In the press-forming apparatus 20 illustrated in
The press-formed product having a hat-shaped cross section that is shown in
When the upper die 40 descends further, as shown in
In a state in which the blank metal plate 70 is sandwiched in this way, the upper die 40 descends further. Thereupon, as shown in
Subsequently, as shown in
The following technology is available as prior art for forming a press-formed product having a hat-shaped cross section.
Japanese Patent Application Publication No. 2009-255116 (Patent Literature 1) discloses technology that uses a pad when performing press-forming by means of a punch and die. According to the technology disclosed in Patent Literature 1, a punch position, a die position and a pad position during press-forming are measured. Based on the measurement values, the position of the pad is controlled so that a relative displacement between the pad and the punch stays within a range of 10 to 20 mm until a relative displacement between the die and the pad from the start of forming becomes zero. By controlling the position of the pad in this way, slackness is formed in the blank metal plate between the punch and the pad, and the slackness that is formed is crushed out in a later stage of the press-forming. By this means, the technology described in Patent Literature 1 enlarges a bending region so that, as a result, spring back can be reduced.
International Application Publication No. WO2011/145679 (Patent Literature 2) discloses technology relating to a press-forming method that uses a die, a bending die and a pad. A press-formed product that is produced using the technology disclosed in Patent Literature 2 has an external shape that curves in an L shape along a longitudinal direction in a planar view. The press-formed product includes a top plate portion, vertical wall portions connected to the top plate portion, and flange portions connected to the vertical wall portions. Specifically, among two side portions of the top plate portion, a vertical wall portion is formed across an entire area at a side portion on a curved inner side. At a side portion on a curved outer side of the top plate portion, a vertical wall portion is formed only in an area from one edge until a position at which the side portion curves. In other words, the press-formed product described in Patent Literature 2 has an incomplete hat-shaped cross section in which a vertical wall portion is missing over a wide area on the curved outer side of the top plate portion.
According to the technology disclosed in Patent Literature 2, a blank metal plate is disposed between a die and pad and a bending die, and press-forming is performed in a state in which the pad is brought adjacent to or into contact with the blank metal plate. At such time, vertical wall portions and flange portions are formed while sliding at least one part of the blank metal plate over a region corresponding to the top plate portion among the entire region of the die. By this means, according to Patent Literature 2, a configuration is adopted that enables suppression of the occurrence of cracks in a flange portion and also enables suppression of the occurrence of wrinkles in a top plate portion in a curved region of a press-formed product.
Vehicle body structural members (front pillar portion, side sill portion and the like) are constituted by individual press-formed products, or are constituted by joining a plurality of press-formed products by spot welding or the like. A lower end of a front pillar portion is joined to a front end of a side sill portion. In the front pillar portion, the portion thereof that is joined to the side sill portion is constituted by a front pillar lower outer reinforcement and a front pillar inner. A press-formed product having a hat-shaped cross section is used for the front pillar lower outer reinforcement. A press-formed product disclosed in the above described Patent Literature 2 may be mentioned as one example thereof.
Such a front pillar lower outer reinforcement is made in a shape that curves in an L shape along the longitudinal direction. This shape is adopted in order to improve performance such as vehicle body rigidity as well as collision safety performance.
As shown in
As shown in
The specific press-formed product 10 can be produced by press-forming using a punch, a die and a blank holder. However, when using a high-strength metal plate, for example, a metal plate having a tensile strength (TS) of 590 MPa or more, as a blank metal plate, cracks or wrinkles are liable to occur in the press-formed product 10.
On the other hand, even in the case of using a metal plate having a tensile strength (TS) of less than 590 MPa as a blank metal plate, if a depth d1 of the first vertical wall portion 10b or a depth d2 of the second vertical wall portion 10c is deep, cracks or wrinkles are liable to occur in the press-formed product 10. Further, cracks or wrinkles are also liable to occur in the press-formed product 10 in a case where the radius of curvature of the first arc-shaped region 10j of the top plate portion is small or a case where the radius of curvature of the second arc-shaped region 10k of the top plate portion is small.
The plate thickness decrease rate was determined by FEM analysis. At that time, a 980 MPa-class dual-phase, high strength steel plate having a plate thickness of 1.6 mm was used as the blank metal plate. The dimensions and shape of the press-formed product were the same as in examples that are described later. The plate thickness decrease rate rtb (%) was calculated by the following Formula (1).
rtb=(tb−t)/tb×100 (1)
In the above Formula (1), tb represents the plate thickness (mm) of the blank metal plate, and t represents the plate thickness (mm) of the press-formed product.
As shown in
Further, in the case of the specific press-formed product shown in
As shown in
As shown in
In the specific press-formed products shown in
As a method for suppressing the occurrence of such cracks or wrinkles, it is conceivable to apply the technology disclosed in the aforementioned Patent Literature 1 to drawing of the specific press-formed product. In this case, since a pad is used in press-forming by a punch and die, it is possible to reduce wrinkles in the Y region to some extent. However, on the other hand, wrinkles will arise in a W region (see the above described
Further, a press-formed product that is adopted as an object of production with the technology disclosed in the aforementioned Patent Literature 2 is a press-formed product having an incomplete hat-shaped cross section in which a vertical wall portion is missing over a wide range. Consequently, it is difficult to apply the technology disclosed in Patent Literature 2 to drawing of the specific press-formed product. If, for instance, the technology disclosed in Patent Literature 2 were applied to drawing of the specific press-formed product, wrinkles would arise in the W region (see the aforementioned
The present invention has been conceived in consideration of the actual circumstances that are described above. An objective of the present invention is to provide a press-forming apparatus having a characteristic described hereunder with regard to a press-formed product that has an external shape that curves in an L shape along a longitudinal direction in a planar view and also has a hat-shaped cross section across approximately an entire area in the longitudinal direction, a method for producing a press-formed product using the forming apparatus, and a press-formed product:
obtainment of a press-formed product in which cracks and wrinkles are reduced.
A press-forming apparatus according to one embodiment of the present invention is a press-forming apparatus for producing a press-formed product having an external shape that curves in an L shape along a longitudinal direction in a planar view.
The press-formed product includes:
a top plate portion including an L-shaped curved region;
a first vertical wall portion that is connected to a side portion on a curved inner side among two side portions of the top plate portion;
a second vertical wall portion that is connected to a side portion on a curved outer side among the two side portions of the top plate portion;
a first flange portion that is connected to the first vertical wall portion; and
a second flange portion that is connected to the second vertical wall portion.
The press-forming apparatus includes a punch, a first blank holder, a second blank holder, a die, a pad, a preceding portion and a restriction mechanism.
The punch has an end face, a first outer side face and a second outer side face that have shapes that correspond to the top plate portion, the first vertical wall portion and the second vertical wall portion, respectively.
The first blank holder is adjacent to a curved inner side of the punch, and is slidable in a pressing direction.
The second blank holder is adjacent to a curved outer side of the punch, and is slidable in the pressing direction.
The die forms a pair with the punch, the first blank holder, and the second blank holder, and includes a first inner side face and a second inner side face that have shapes that correspond to the first vertical wall portion and the second vertical wall portion, respectively, and a first guide face and a second guide face that face the first blank holder and the second blank holder, respectively.
The pad constitutes one part of the die and is slidable in the pressing direction, and among an entire region of the end face of the punch, faces at least a region that corresponds to the curved region of the top plate portion.
The preceding portion constitutes one part of the die and is slidable in the pressing direction, and among an entire region of the first guide face and the first inner side face, includes at least a region that corresponds to the curved region of the top plate portion.
Operations of the press-forming apparatus are as described below.
When pushing the punch into the die by relatively moving the punch and the die in the pressing direction to form a metal plate into the press-formed product, the first guide face of the preceding portion precedes the second guide face of the die, and the first vertical wall portion and the first flange portion are formed. Thereafter, sliding of the first blank holder and the preceding portion relative to the punch is restricted by the restriction mechanism, and pushing of the punch into the die is continued in the restricted state and the second vertical wall portion and the second flange portion are formed.
The above described press-forming apparatus can have a configuration that further includes a cushion and a stopper.
The cushion slidably supports the first blank holder in the pressing direction via a cushion pin.
The stopper limits sliding of the first blank holder.
In the case of this configuration, by separating the cushion pin and the first blank holder while limiting sliding of the first blank holder with the stopper, the restriction mechanism restricts sliding of the first blank holder, and restricts sliding of the preceding portion following restriction of the first blank holder.
The above described press-forming apparatus can adopt a configuration that further includes a pressurizing mechanism instead of the above described configuration.
The pressurizing mechanism slidably supports the first blank holder in the pressing direction.
In the case of this configuration, the restriction mechanism restricts the first blank holder by limiting sliding of the first blank holder, and restricts sliding of the preceding portion following restriction of the first blank holder.
A method for producing a press-formed product according to one embodiment of the present invention is a method that, when producing the above described press-formed product from a metal plate by press-forming, executes formation of the first vertical wall portion and the first flange portion prior to formation of the second vertical wall portion and the second flange portion.
The described production method can adopt the following configuration.
The method for producing the press-formed product uses the above described press-forming apparatus, and includes a holding process and a forming process.
In the holding process, in a state in which the first guide face of the preceding portion precedes the second guide face of the die, the metal plate is sandwiched by the first blank holder, the second blank holder and the pad.
In the forming process, by relatively moving the punch and the die in the pressing direction, the punch is pushed into the die to form the metal plate into the press-formed product.
The forming process includes a first step and a second step.
In the first step, in a state in which the first guide face of the preceding portion precedes the second guide face of the die, pushing of the punch into the die is performed to form the first vertical wall portion and the first flange portion.
In the second step, sliding of the first blank holder and the preceding portion relative to the punch is restricted by the restriction mechanism, and pushing of the punch into the die is continued in the restricted state to form the second vertical wall portion and the second flange portion.
A press-formed product according to one embodiment of the present invention has an external shape that curves in an L shape along a longitudinal direction in a planar view.
The press-formed product includes:
a top plate portion including an L-shaped curved region;
a first vertical wall portion that is connected to a side portion of a curved inner side among two side portions of the top plate portion;
a second vertical wall portion that is connected to a side portion of a curved outer side among the two side portions of the top plate portion;
a first flange portion that is connected to the first vertical wall portion; and
a second flange portion that is connected to the second vertical wall portion;
wherein, a tensile strength thereof is 590 MPa or more.
A press-forming apparatus, a method for producing a press-formed product using the forming apparatus, and a press-formed product of the present invention have the following remarkable advantageous effect:
obtainment of a press-formed product in which cracks and wrinkles are reduced.
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To achieve the above described objective, the present inventors preformed various experiments and conducted concentrated studies. As a result, as shown in
Further, by using the blank holders 32 and 33 together with the pad 41, the generation of wrinkles in the Y region of the curved outer side of the first arc-shaped region 10j of the top plate portion can be reduced. As a result, it is possible to reduce changes in the plate thickness of the press-formed product.
Hereunder, embodiments of the present invention are described while referring to the drawings.
The press-forming apparatus 20 includes a ram 61, an upper die 40, a lower die 30, a bolster 62 and a cushion 35. The ram 61 slides in a pressing direction (vertical direction). The cushion 35 is arranged below the bolster 62. The cushion 35 generates a uniform pressure in the upward direction by means of a spring or a fluid pressure or the like. Note that a blank metal plate 70 is also shown in
The lower die 30 includes a punch 31, a first blank holder 32 and a second blank holder 33. The punch 31 has a die impression in which the shape of the press-formed product 10 is reflected. In other words, the punch 31 has an end face 31a which has a shape that corresponds to the top plate portion 10a of the press-formed product 10. In addition, the punch 31 has a first outer side face 31b which has a shape that corresponds to the first vertical wall portion 10b, and also has a second outer side face 31c which has a shape that corresponds to a second vertical wall portion 10c. Accordingly, similarly to the press-formed product 10, the shape in a planar view of the punch 31 is a shape that curves in an L shape along the longitudinal direction.
The first blank holder 32 is arranged on a curved inner side of the punch 31, and is adjacent to the punch 31. The second blank holder 33 is arranged on a curved outer side of the punch 31, and is adjacent to the punch 31.
The first blank holder 32 and the second blank holder 33 are mounted at an upper end of a cushion pin 34, respectively. The cushion pins 34 penetrate through the bolster 62 and are supported so as to be individually movable in the pressing direction (vertical direction). The lower ends of the cushion pins 34 are pressed against the cushion 35. Therefore, the first blank holder 32 and the second blank holder 33 are slidably supported in the pressing direction while an upward restoring force is imparted thereto by the cushion 35 via the cushion pins 34.
A stopper 56 that is fixed to the press-forming apparatus and that is used for limiting a sliding movement of the first blank holder 32 is provided on the cushion pin 34 that supports the first blank holder 32. The stopper 56 constitutes a restriction mechanism that restricts sliding of the first blank holder 32, and also restricts sliding of a preceding portion 54 of a die that is described later. The first blank holder 32 is mounted to the cushion pin 34 in a state in which the first blank holder 32 is detachable from the cushion pin 34.
The upper die 40 includes a die 50 (51 to 53) and the pad 41. The die 50 is constituted by a die plate 51, a first die 52 and a second die 53, and has a die impression in which the shape of the press-formed product 10 in a state in which these dies are integrated is reflected. In terms of the die impression, the pad 41 constitutes one part of the die 50, and has an end face having a shape that corresponds to the top plate portion 10a of the press-formed product 10. In other words, the pad 41 is arranged facing the end face 31a of the punch 31.
The first die 52 faces the first blank holder 32. In other words, the first die 52 is arranged on the curved inner side of the punch 31 (press-formed product 10). The first die 52 has a first guide face 50c which has a shape that corresponds to the first flange portion 10d of the press-formed product 10. In addition, the first die 52 has a first inner side face 50a which has a shape that corresponds to the first vertical wall portion 10b of the press-formed product 10. The first inner side face 50a is also a shape that corresponds to the first outer side face 31b of punch 31.
The second die 53 faces the second blank holder 33. In other words, the second die 53 is arranged on the curved outer side of the punch 31 (press-formed product 10). The second die 53 has a second guide face 50d which has a shape that corresponds to the second flange portion 10e of the press-formed product 10. In addition, the second die 53 has a second inner side face 50b which has a shape that corresponds to the second vertical wall portion 10c of the press-formed product 10. The second inner side face 50b is also a shape that corresponds to the second outer side face 31c of the punch 31.
The preceding portion 54 is provided in the first die 52 that is arranged on the curved inner side of the punch 31 (press-formed product 10). Among the entire region of the first guide face 50c and the first inner side face 50a, the preceding portion 54 includes at least a region that corresponds to the curved region of the top plate portion 10a of the press-formed product 10. In other words, the preceding portion 54 constitutes one part of the first guide face 50c and the first inner side face 50a of the first die 52. As described using
The preceding portion 54 may be integrated with the first die 52, or may be a portion that is separated and independent from the first die 52. In
The pad 41 is supported via a pad pressurizing mechanism (for example, a spring, rubber, a gas cylinder or a hydraulic cylinder) 42. By this means, the pad 41 is slidable in the pressing direction. Of the entire region of the end face 31a of the punch 31, the pad 41 faces at least a region that corresponds to the curved region of the top plate portion 10a of the press-formed product 10. In other words, the pad 41 constitutes one part of the die 50. For example, as described using
The specific press-formed product 10 illustrated in the above described
In the state before forming, as shown in
From this state, the upper die 40 descends and the punch 31 and the die 50 move relatively in the pressing direction. Thereupon, as shown in
Next, the upper die 40 descends further. Thereupon, as shown in
The restoring force of the preceding portion pressurizing mechanism 55 that is imparted to the preceding portion 54 is greater than the restoring force of the cushion 35 that is imparted to the first blank holder 32. Consequently, the first blank holder 32 is pushed downward by the preceding portion 54, and as shown in
In the state in which the blank metal plate 70 is sandwiched in this manner, the upper die 40 descends further. Thereupon, in the state in which the first guide face 50c of the preceding portion 54 precedes the second guide face 50d of the second die 53, the punch 31 is pressed into the die 50, and the blank metal plate 70 is worked. In due course, as shown in
When the first vertical wall portion 10b and first flange portion 10d are formed in advance from the blank metal plate 70, the blank metal plate 70 is drawn to the preceding portion 54 side (first die 52 side) on the curved inner side. More specifically, the blank metal plate 70 is drawn in a direction indicated by a solid line arrow in the above described
As shown in
The upper die 40 then descends further. Thereupon, because sliding of the first blank holder 32 and the preceding portion 54 relative to the punch 31 is restricted, the first blank holder 32 and the cushion pin 34 separate from each other, and the preceding portion 54 is pressed to the die plate 51 side. On the other hand, the second die 53 descends, and working of the second vertical wall portion 10c and the second flange portion 10e continues.
Subsequently, as shown in
According to the press-forming of the present embodiment, when forming of the first vertical wall portion 10b and the first flange portion 10d is substantially completed, the blank metal plate 70 is drawn in towards the preceding portion 54 side (first die 52 side) on the curved inner side. By this means, a state is entered in which there is a surplus of the blank metal plate 70 in the second arc-shaped region 10k of the top plate portion and the vicinity thereof. From this state, forming of the second vertical wall portion 10c by the end face 31a and the second outer side face 31c of the punch 31 progresses and is completed. Therefore, even when a high-strength metal plate, for example, a metal plate having a tensile strength (TS) of 590 MPa or more is used as the blank metal plate 70, a thickness reduction in the X region (top plate portion 10a; see
Further, according to the press-forming of the present embodiment, the pad 41 butts against the blank metal plate 70 on at least the curved outer side of the first arc-shaped region 10j of the top plate portion. As a result of the blank metal plate 70 being sandwiched by the pad 41 and the punch 31, the formation of wrinkles can be reduced in the Y region (top plate portion 10a; see
In particular, by using the second blank holder 33, formation of wrinkles in the W region (see
The occurrence of cracks in the Z region (see
As described above, according to the press-forming of the present embodiment, since a thickness reduction in the press-formed product 10 is decreased, the occurrence of cracks can be reduced. Furthermore, wrinkles can be reduced. Consequently, a change in the plate thickness of the press-formed product 10 can be reduced. Therefore, it is possible to obtain the press-formed product 10 in which cracks and wrinkles are reduced. The press-formed product 10 is formed using the blank metal plate 70 which has a tensile strength of 590 MPa or more by the press-forming of the present embodiment. Accordingly, the tensile strength of the press-formed product 10 is 590 MPa or more, preferably 980 MPa or more, and further preferably 1180 MPa or more.
The press-forming of the present embodiment is also applicable to a case where a low-strength metal plate is used as the blank metal plate 70. In such a case, even if the radius of curvature of the first arc-shaped region 10j of the top plate portion is small, the press-formed product 10 in which a change in the plate thickness as well as cracks and wrinkles are reduced can be obtained. Naturally, a problem will not arise even if the radius of curvature of the second arc-shaped region 10k of the top plate portion is small. Furthermore, a problem will not arise even if the depth d1 of the first vertical wall portion 10b or the depth d2 of the second vertical wall portion 10c is deep. Accordingly, the degree of freedom in designing the shape of a press-formed product is increased by using the press-forming of the present embodiment.
The press-forming apparatus 20 of the second embodiment is based on the configuration of the press-forming apparatus 20 of the first embodiment illustrated in the above described
In the second embodiment, sliding of the first blank holder 32 is limited by the stopper 56 through the first blank holder pressurizing mechanism 36. The first blank holder 32 is restricted as a result of such limiting, and sliding of the preceding portion 54 is restricted following such restriction of the first blank holder 32.
In the case of the third embodiment, a die parting line exists between the preceding portion 54 and the first die main body 52a. There is a risk that the die parting line will be transferred onto the press-formed product 10. Therefore, from the viewpoint of ensuring the surface quality of the press-formed product 10, it is preferable to adopt the preceding portion 54 as described in the foregoing first and second embodiments.
In the above described first to third embodiments, the preceding portion 54 constitutes the entire area in the width direction of the first guide face 50c. However, as long as press-forming (drawing) of the blank metal plate 70 can be performed, a form may also be adopted in which the preceding portion 54 constitutes one part in the width direction of the first guide face 50c.
Further, although the preceding portion 54 may be provided across the entire area in the longitudinal direction of the first die 52, a configuration may also be adopted in which the preceding portion 54 is partially provided in the longitudinal direction of the first die 52. If the preceding portion 54 is partially provided, a die parting line will exist. The die parting line may be appropriately set, for example, in accordance with constraints with respect to the surface quality of the press-formed product 10, and furthermore, in accordance with an offset load applied to a die and a press machine. Indeed, from the viewpoint of ensuring the surface quality of the press-formed product 10, it is preferable that the preceding portion 54 is provided across the entire area in the longitudinal direction of the first die 52.
In short, the pad 41 is arranged so as to butt against at least the wrinkle occurrence region of the top plate portion 10a. In many cases, the wrinkle occurrence region exists in the Y region (see
In this case, as described above, the occurrence of cracks in the Z region (see
In the press-forming of the present embodiment, the first guide face 50c of the preceding portion 54 is arranged so as to precede the second guide face 50d of the second die 53. A preceding amount m (unit: mm; see
The arrangement of the preceding portion 54 at an early stage of a pushing-in process can be evaluated by means of a height difference n (unit: mm; see the above described
In the press-forming of the present embodiment, whatever value the height difference n between the first guide face 50c and the second guide face 50d is among a positive value, 0 (zero) and a negative value, the occurrence of cracks in the X region can be reduced. From the viewpoint of reducing the occurrence of cracks in the X region to a greater extent, preferably the height difference n between the first guide face 50c and the second guide face 50d is made a positive value, and the state in the early stage of the pushing-in process is a state in which the first guide face 50c of the preceding portion 54 protrudes relative to the second guide face 50d of the second die 53. On the other hand, from the viewpoint of an offset load that is loaded on the die and the press machine as well as from the viewpoint of reducing the occurrence of wrinkles while improving the production efficiency, preferably the height difference n between the first guide face 50c and the second guide face 50d is made a smaller value than the depth d1 of the first vertical wall portion 10b.
A boundary portion 10i between the second vertical wall portion 10c and the second flange portion 10e of the press-formed product 10 includes a substantially quarter arc-shaped region 10q (second arc-shaped region of the flange portion) that curves along a curved region of the top plate portion 10a (see
A configuration that maintains a distance between the second blank holder 33 and the second die 53 in a state in which the distance is greater than the plate thickness of the blank metal plate 70 can be realized, for example, by providing a step height in mutually facing surfaces of the second blank holder 33 and the second die 53. Further, for example, such a configuration can be realized by providing, between the second blank holder 33 and the second die 53, a distance block that serves as a die surface contacting portion of the second blank holder 33 and the second die 53. Such a configuration can also be realized by combining the second blank holder 33 and the second die 53.
In the case of adopting a configuration that maintains a distance between the second blank holder 33 and the second die 53 in a state in which the distance is greater than the plate thickness of the blank metal plate 70, if the distance between the second blank holder 33 and the second die 53 is too large, there is a risk that wrinkles will arise in the W region (see
tb×1.01≦d≦tb×1.50 (2)
In the above Formula (2), tb represents the plate thickness (mm) of the blank metal plate.
As described above, in a case where cracks in the Z region (see
By this means, a thickness reduction in the X region (see
In the press-forming of the present embodiment there is not limitation with respect to the order of sandwiching the blank metal plate 70. Sandwiching using the pad 41 may be executed after sandwiching by the first blank holder 32 and second blank holder 33 as in the working processes illustrated in the above described
Although in the press-forming apparatus illustrated in the above described
Note that, a restriking process may be added after the press-forming of the present embodiment. In the restriking process a region having an incomplete shape (for example, a minute R portion or the like) is finished into a final shape.
The specific press-formed product 10 that is produced by the press-forming of the present embodiment is applied not only to a front pillar lower outer reinforcement, but also to structural members such as a side sill inner, a side sill outer reinforcement rear, a front side member and a rear side member.
In the case of a specific press-formed product that is applied to the aforementioned structural members, a central angle of the first arc-shaped region 10j of the top plate portion and the second arc-shaped region 10k of the top plate portion is designed to be, for example, 15 to 120°. Further, the radius of curvature of the first arc-shaped region 10j of the top plate portion is designed to be, for example, 30 to 600 mm. The radius of curvature of the second arc-shaped region 10k of the top plate portion is designed to be, for example, 10 to 600 mm, or ∞ (a straight line). The depth d1 of the first vertical wall portion 10b is designed to be, for example, 20 to 300 mm, and the depth d2 of the second vertical wall portion 10c is designed to be, for example, 20 to 300 mm.
More specifically, in a case of using the specific press-formed product as a rear side member, the central angle of the arc-shaped regions 10j and 10k is set to, for example, 15 to 85°. Further, the radius of curvature of the first arc-shaped region 10j of the top plate portion is set to, for example, 30 to 600 mm. The radius of curvature of the second arc-shaped region 10k of the top plate portion is set to, for example, 30 to 600 mm. The depth d1 of the first vertical wall portion is set to, for example, 30 to 300 mm, and the depth d2 of the second vertical wall portion is set to, for example, 30 to 300 mm.
In a case of using the specific press-formed product as a front pillar lower outer reinforcement, the central angle of the arc-shaped regions 10j and 10k is set to, for example, 60 to 120°. Further, the radius of curvature of the first arc-shaped region 10j of the top plate portion is set to, for example, 30 to 200 mm. The radius of curvature of the second arc-shaped region 10k of the top plate portion is set to, for example, 10 to 200 mm. The depth d1 of the first vertical wall portion and the depth d2 of the second vertical wall portion are set to, for example, 20 to 200 mm.
In the case of using the specific press-formed product as a front pillar inner, the central angle of the arc-shaped regions 10j and 10k is set to, for example, 60 to 120°. Further, the radius of curvature of the first arc-shaped region 10j of the top plate portion is set to, for example, 30 to 200 mm. The radius of curvature of the second arc-shaped region 10k of the top plate portion is set to, for example, 10 to 200 mm. The depth d1 of the first vertical wall portion and the depth d2 of the second vertical wall portion are set to, for example, 20 to 200 mm.
In the case of using the specific press-formed product as a side sill outer reinforcement rear, the central angle of the arc-shaped regions 10j and 10k is set to, for example, 15 to 85°. Further, the radius of curvature of the first arc-shaped region 10j of the top plate portion is set to, for example, 30 to 400 mm. The radius of curvature of the second arc-shaped region 10k of the top plate portion is set to, for example, 70 to ∞ (a straight line) mm. The depth d1 of the first vertical wall portion and the depth d2 of the second vertical wall portion are set to, for example, 20 to 200 mm.
As shown in
Further, in the first stage, the second die 53 that is arranged on the curved outer side of the punch 31 is fixed to the die plate 51, similarly to the first to third embodiments. However, the die impression of the second die 53 is a portion in which the shape of the finished product is partly reflected. In other words, the depth in the pressing direction of the inner side face 50b of the second die 53 is shallower than the depth of the second vertical wall portion of the finished product.
With regard to the lower die 30 used in the first stage, the stopper 56 that limits a sliding movement of the first blank holder 32 as described in the first to third embodiments is not provided.
As shown in
Further, in the second stage, similarly to the first to third embodiments, the second die 53 that is arranged on the curved outer side of the punch 31 is fixed to the die plate 51. Furthermore, similarly to the first to third embodiments, the die impression of the second die 53 is a portion in which the shape of the finished product is reflected.
With regard to the lower die 30 that is used in the second stage, the first blank holder 32 that is adjacent to the curved inner side of the punch 31 is integrated with the punch 31. In other words, the cushion pin 34 that supports the first blank holder 32 in the configurations of the first to third embodiments is not provided.
As shown in
As shown in
In the fourth embodiment also, because forming of the first vertical wall portion 10b and the first flange portion 10d precedes forming of the second vertical wall portion 10c and the second flange portion 10e, the same advantageous effects as in the first to third embodiments are obtained.
FEM analysis as described in the following Examples 1 and 2 was performed to verify the effect of the present invention.
In the FEM analysis of Example 1, a blank metal plate was formed into a specific press-formed product using the press-forming apparatus of the above described first embodiment. The plate thickness decrease rate, cracks and wrinkles in respective portions were evaluated with respect to the press-formed product that was obtained.
A dual-phase, high strength steel plate having a tensile strength of the 980 MPa-class and a plate thickness of 1.6 mm was adopted as the blank metal plate. The shape of the blank metal plate was set so that a portion having excess metal with a width of a maximum of around 97 mm is formed on the curved inner side of the first flange portion having a width of approximately 15 mm in the press-formed product that is obtained.
The radius of curvature of the first arc-shaped region of the top plate portion of the press-formed product was set as 80 mm. The radius of curvature of the second arc-shaped region of the top plate portion of the press-formed product was set as 36 mm. The depth d1 of the first vertical wall portion was set as 44 mm, and the depth d2 of the second vertical wall portion was set as 51 mm.
The preceding portion was arranged so that the preceding amount m was 25 mm, and the height difference n between the first guide face and the second guide face was set as 18 mm. The pressing force of the pad was set as approximately 100 kN. The pressing forces of the first blank holder and second blank holder were set in accordance with the actual length in the longitudinal direction of the first flange portion and the second flange portion, respectively, with the pressing force of the first blank holder being set to approximately 160 kN and the pressing force of the second blank holder being set to approximately 260 kN. The pressing force of the preceding portion was set to approximately 600 kN.
The preceding portion was provided across the entire area in the longitudinal direction of the first die. On the other hand, the pad was provided in the region 10m shown in the above described
The region 10o of the first flange portion 10d is taken as a region on the curved inner side of the first arc-shaped region 10l of the flange portion, the entire region that is rearward in the longitudinal direction from the arc-shaped region 10l, and a neighboring region to the front in the longitudinal direction of the arc-shaped region 10l. The region 10p of the second flange portion 10e is taken as a region on the curved outer side of the second arc-shaped region 10q of the flange portion, the entire region that is rearward in the longitudinal direction from the arc-shaped region 10q, and a neighboring region to the front in the longitudinal direction of the arc-shaped region 10q.
The results shown in
In the FEM analysis of Example 2, the specific press-formed product was formed using a similar press-forming apparatus and blank metal plate as in Example 1, and the preceding amount m of the preceding portion, that is, the stroke difference between the preceding portion and the second die was changed to various values. The plate thickness decrease rate, cracks and wrinkles in respective portions were evaluated with respect to the press-formed product that was obtained. Note that, in the press-formed product of Example 2, the depth d1 of the first vertical wall portion and the depth d2 of the second vertical wall portion were made deeper than the corresponding depth d1 and depth d2 in the press-formed product of Example 1. In other words, in the press-formed product of Example 2, the depth d1 of the first vertical wall portion was made 55 mm and the depth d2 of the second vertical wall portion was made 60 mm.
The results shown in
The present invention can be effectively used in the production of structural members of an automobile body.
Number | Date | Country | Kind |
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2013-253148 | Dec 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/006004 | 12/2/2014 | WO | 00 |