The present invention relates to a press-formed product for use in automobiles, in various vehicles other than automobiles, in general machinery, and in ships and vessels and the like, and more particularly relates to a press-formed product having a bend section, as well as a method and an equipment line for producing the press-formed product.
Press-formed products having a bend section are used, for example, in frame members of an automobile body (for example: cross members, side members, side sills, pillars and the like), and are used in various components of an automobile (for example: door impact beams, toe-control links, suspension arms and the like). The aforementioned press-formed products are obtained by bending a steel plate as a starting material using a press. In recent years, there is a demand to improve fuel consumption in order to contribute to global environmental protection, and there is also a demand for enhanced safety at the time of a collision. Therefore, press-formed products are being increasingly made with thinner walls using high strength steel plates. However, there is a contrary relation between enhancing the strength of the starting material and the workability (particularly the bendability) of the starting material.
In general, the bendability of the steel plate 1 is evaluated based on a limit R/t. Here, “R” represents a minimum bending radius with which bending can be performed without the occurrence of cracking, and “t” represents the thickness of the steel plate 1. In recent years, high strength steel plates having a tensile strength of 980 MPa or more and a small degree of elongation have begun to be used as the starting material for the aforementioned frame members. Further, high strength steel plates having a tensile strength of 590 MPa or more are being used as the starting material for suspension components (for example, suspension arms). In short, as the strength of the steel plate 1 increases, there is a tendency for the limit R/t to also increase. Consequently, if the bending radius of the bend section 5 of the press-formed product 2 is designed to be a small radius, the steel plate 1 will crack. On the other hand, if the bending radius of the bend section 5 of the press-formed product 2 is designed to be a large radius, the rigidity of the frame member or suspension component will decrease and the impact energy absorption performance thereof will decline. Accordingly, there is a strong need for a processing method that can decrease the limit R/t when producing the press-formed product 2 having the bend section 5 from a high strength steel plate.
In the bending method disclosed in Patent Literature 1, a bend section 8 of the press-formed product 7 formed by press working that is divided into two steps. Specifically, as shown in
In the press working in the second step, as shown in
According to the bending method disclosed in Patent Literature 1, cracking does not occur in the press working in the first step because the bending radius R1 is large. In addition, in the press working in the second step, tensile strain that arises in the outer surface of the bend section 8 is reduced, and the occurrence of cracking can be suppressed.
In the bending method disclosed in Patent Literature 1, a front end angle θ2 of the punch 13 used in the second step is the same as a front end angle θ1 of the punch 9 used in the first step. In other words, the interior angle of the bend section 8 of the press-formed product 7 is the same as the interior angle of the bend section 11 of the intermediate formed product 12.
Patent Literature 1: Japanese Patent Application Publication No. 2010-172912
Patent Literature 1 discloses that the limit R/t can be made 0 when producing a press-formed product having a bend section using a stainless steel plate that has high tensile strength of 889 MPa and in which the elongation is a high value of 59%. However, even when using the bending method disclosed in Patent Literature 1, for example, in a case of using a metal plate having high tensile strength and a small degree of elongation such as in a high strength steel plate, there is a risk that cracking will occur at the bend section. Accordingly, there is a need to enable reliable lowering of the limit R/t.
One objective of the present invention is to provide a press-formed product in which tensile strain in an outer surface of the bend section is small and cracking is suppressed, even though the product has a bend section with a small bending radius and a tensile strength of 590 MPa or more. Another objective of the present invention is to provide a production method and a production equipment line that can produce the aforementioned press-formed product.
A press-formed product according to one embodiment of the present invention is made from a metal plate having a tensile strength of 590 MPa or more, and includes a pair of flat sections and a bend section connecting the pair of flat sections. In the press-formed product, at a cross section, a plate thickness increases as a distance from a vicinity of a top part of the bend section increases, the plate thickness decreases as a distance from a vicinity of an end of the bend section increases, and thereafter the plate thickness increases again, and beyond a position separated by a distance corresponding to 1.5 times an original plate thickness from a position of an end of the bend section, the plate thickness becomes the original plate thickness.
In the aforementioned press-formed product, a ratio “t2/t1” between an average value t2 of a plate thickness in an area from the position of the end of the bend section to the position separated therefrom by the distance corresponding to 1.5 times the original plate thickness, and a plate thickness t1 at the top part of the bend section is preferably less than 1.01.
In a case where the aforementioned press-formed product includes a top plate part, two vertical wall parts, and a ridge line part connecting the top plate part and the respective vertical wall parts, preferably the top plate part and the vertical wall part constitute the flat section, and the ridge line part constitutes the bend section.
In a case where the aforementioned press-formed product includes a top plate part, two vertical wall parts, an upper-side ridge line part connecting the top plate part and the respective vertical wall parts, two flange parts, and a lower-side ridge line part connecting the respective vertical wall parts and the respective flange parts, preferably the top plate part and the vertical wall part constitute the flat section, and the upper-side ridge line part constitutes the bend section, and/or the vertical wall part and the flange part constitute the flat section, and the lower-side ridge line part constitutes the bend section.
Preferably the aforementioned press-formed product is made from a steel plate having a tensile strength or 1180 MPa or more. The tensile strength may be 780 MPa or more, or may be 980 MPa or more.
A production method for producing a press-formed product according to one embodiment of the present invention is a method for producing a press-formed product including a pair of flat sections, and a bend section connecting the pair of flat sections, and in which a bending radius of the bend section is represented by R2 and an interior angle formed by the pair of flat sections is represented by θ2. The production method includes a starting material preparation step, a first forming step and a second forming step. In the starting material preparation step, a metal plate having a tensile strength or 590 MPa or more is prepared. In the first forming step, the metal plate is subjected to press working using a die assembly to form an intermediate formed product having a bend section with a bending radius of R1 (mm) and an interior angle of θ1 (°) at a portion corresponding to the bend section of the press-formed product. In the second forming step, the intermediate formed product is subjected to press working using a die assembly to form the press-formed product having a bend section with a bending radius of R2 (mm) and an interior angle of θ2 (°) at a portion of the bend section of the intermediate formed product. The bending radius R1 and the interior angle θ1 of the intermediate formed product and the bending radius R2 and the interior angle θ2 of the press-formed product satisfy conditions of Formulae (1) to (3) hereunder.
1.05<A1/A2 (1)
1.0<R1/R2 (2)
A
1
A
2<6.0/(R1/R2) (3)
In the above Formulae, A1 (°) is a supplementary angle of the interior angle θ1 of the intermediate formed product, which is represented by Formula (A) hereunder, and A2 (°) is a supplementary angle of the interior angle θ2 of the press-formed product, which is represented by Formula (B) hereunder.
A
1=180−θ1 (A)
A
2=180−θ2 (B)
In the aforementioned production method, preferably the bending radius R1 and the interior angle θ1 of the intermediate formed product and the bending radius R2 and the interior angle θ2 of the press-formed product satisfy conditions of Formulae (1), (4) and (5) hereunder.
1.05<A1/A2 (1)
1.5<R1/R2 (4)
A
1
/A
2<3.5/(R1/R2) (5)
In the aforementioned production method, preferably a punch and a die are used as the die assembly in the first forming step, and a punch and a die are used as the die assembly in the second forming step. In this case, in the second forming step, preferably, when performing press working, the intermediate formed product is restrained and positioned by a die pad provided in the die and an inner pad provided in the punch.
A production equipment line for producing a press-formed product according to one embodiment of the present invention is an equipment line for producing a press-formed product including a pair of flat sections, and a bend section connecting the pair of flat sections, and in which a bending radius of the bend section is represented by R2 and an interior angle formed by the pair of flat sections is represented by θ2. The production equipment line includes a first press apparatus and a second press apparatus. The first press apparatus includes a punch and a die for forming an intermediate formed product having a bend section with a bending radius of R1 (mm) and an interior angle of θ1 (°) at a portion corresponding to the bend section of the press-formed product. The second press apparatus includes a punch and a die for forming the press-formed product having a bend section with a bending radius of R2 (mm) and an interior angle of θ2 (°) at a portion of the bend section of the intermediate formed product. The bending radius R1 and the interior angle θ1 of the intermediate formed product and the bending radius R2 and the interior angle θ2 of the press-formed product satisfy the conditions of the aforementioned Formulae (1) to (3).
In the aforementioned production equipment line, preferably the bending radius R1 and the interior angle θ1 of the intermediate formed product and the bending radius R2 and the interior angle θ2 of the press-formed product satisfy the conditions of the aforementioned Formulae (1), (4) and (5).
In the aforementioned production equipment line, preferably the second press apparatus further includes a die pad provided in the die and an inner pad provided in the punch, and when performing press working, the intermediate formed product is restrained and positioned by the die pad and the inner pad.
The press-formed product of the present invention has a bend section with a small bending radius and has a tensile strength of 590 MPa or more, and tensile strain in an outer surface of the bend section of the press-formed product is small and cracking is suppressed. The production method and the production equipment line of the present invention can produce such a press-formed product.
The present inventors conducted repeated intensive studies to solve the above described problem, and as a result obtained the findings described in (a) to (c) hereunder.
(a) The press-formed product having a pair of flat sections and a bend section connecting the pair of flat sections will now be discussed. In the press-formed product, a bending radius at the bend section is R2 (mm), and an interior angle formed by the pair of flat sections is θ2 (°). A high strength steel plate having a tensile strength of 590 MPa or more is adopted as a starting material, and the press-formed product is produced by press working that is divided into two steps. In press working in a first step, using a punch and a die as a die assembly, an intermediate formed product is formed that has a bend section with a bending radius of R1 (mm) and an interior angle of θ1 (°) at a portion corresponding to the bend section of the press-formed product in the steel plate. In press working in a second step, using a punch and a die as a die assembly, the press-formed product is formed in which the bend section of the intermediate formed product is formed into a bend section with a bending radius of R2 (mm) and an interior angle of θ2 (°).
In this case, to suppress the occurrence of cracking at the bend section, it is sufficient that tensile strain that occurs in the outer surface (hereunder, also referred to as “surface layer strain”) of the bend section is small. A perimeter ratio “L1/L2” between a perimeter L1 (mm) of the bend section formed in the first step and a perimeter L2 (mm) of the bend section formed in the second step is a factor involved in determining the size of the surface layer strain that occurs in the bend section. The perimeters L1 and L2 of the bend section are lengths in the circumferential direction at a cross section of the bend section, and are represented by the following Formulae (i) and (ii).
L
1
=π×R
1×(180−θ1)/180 (i)
L
2
=π×R
2×(180−θ2)/180 (ii)
Further, the supplementary angle (that is, the exterior angle) A1 (°) of the interior angle θ1 at the bend section that is formed in the first step is represented by the following Formula (A). The supplementary angle (that is, the exterior angle) A2 (°) of the interior angle θ2 at the bend section that is formed in the second step is represented by the following Formula (B).
A
1=180−θ1 (A)
A
2=180−θ2 (B)
Based on the aforementioned Formulae (i), (ii), (A) and (B), the perimeter ratio “L1/L2” of the bend section is represented by the following Formula (iii).
L
1
/L
2=(A1×R1)/(A2×R2) (iii)
Accordingly, the bending radius R1 and interior angle θ1 (exterior angle A1) of the bend section of the intermediate formed product that is formed in the first step and the bending radius R2 and interior angle θ2 (exterior angle A2) of the bend section of the press-formed product that is formed in the second step are mutually involved in determining the size of surface layer strain that arises in the bend section.
If the aforementioned bending radius R1 and interior angle θ1 (exterior angle A1) and the aforementioned bending radius R2 and interior angle θ2 (exterior angle A2) satisfy the conditions of the following Formulae (1) to (3), an occurrence region of surface layer strain that occurs in the bend section expands as a result of performing the press working in the first step and the press working in the second step. Consequently, the surface layer strain in the bend section of the press-formed product decreases. By this means, even when a steel plate having a tensile strength of 590 MPa or more is used as a starting material, the occurrence of cracking can be suppressed and a press-formed product having a bend section with a smaller bending radius can be produced. More preferably, the aforementioned bending radius R1 and interior angle θ1 (exterior angle A1) and the aforementioned bending radius R2 and interior angle θ2 (exterior angle A2) satisfy the conditions of the following Formulae (1), (4) and (5).
1.05<A1/A2 (1)
1.0<R1/R2 (2)
A
1
/A
2<6.0/(R1/R2) (3)
1.5<R1/R2 (4)
A
1
/A
2<3.5/(R1/R2) (5)
The above Formula (1) means that the exterior angle A1 of the bend section formed in the first step is larger than the exterior angle A2 of the bend section formed in the second step. In other words, the above Formula (1) means that, based on the above Formulae (A) and (B), the interior angle θ1 of the bend section formed in the first step is smaller than the interior angle θ2 of the bend section formed in the second step. The sizes of the respective interior angles θ1 and θ2 (exterior angles A1 and A2) are set in accordance with the design dimensions of the press-formed product. In practice, the sizes of the respective interior angles θ1 and θ2 are set within a range of 90° to 120°.
The above Formulae (2) and (4) mean that the bending radius R1 of the bend section formed in the first step is larger than the bending radius R2 of the bend section formed in the second step. The sizes of the respective bending radii R1 and R2 are set in accordance with the design dimensions of the press-formed product. Specifically, the bending radii R1 and R2 are set as follows.
A value of R/t for which there is a risk of cracking occurring at the bend section is from 0.5 to 3.0. Here, “R” represents the bending radius at the time of bending, and “t” represents the plate thickness of the metal plate on which the bending is executed. Normally, an average plate thickness of a flat section of a press-formed product, that is, the plate thickness of the metal plate that is the starting material is approximately 0.5 to 3.2 mm in the case of a sheet. In the case of a thick plate, the plate thickness is approximately 3.2 to 30 mm, and is more than 30 mm in some cases. In the present embodiment, with respect to bending of metal plates that have such various kinds of plate thicknesses, cases in which there is a risk of cracking occurring at a bend section are taken as the object of the embodiment.
That is, in a case where the plate thickness is, for example, 0.5 mm, the bending radius R of the bend section of the press-formed product, that is, the bending radius R2 of the bend section formed in the second step, is approximately 0.25 to 1.5 mm. In this case, the bending radius R1 of the bend section that is formed in the first step is approximately 0.26 to 8.2 mm, and preferably is approximately 0.38 to 5.2 mm. In a case where the plate thickness is, for example, 1.0 mm, the aforementioned bending radius R2 is approximately 0.5 to 3.0 mm. In this case, the aforementioned bending radius R1 is approximately 0.55 to 16.0 mm, and preferably is approximately 0.8 to 10.0 mm. In a case where the plate thickness is, for example, 3.2 mm, the aforementioned bending radius R2 is approximately 1.5 to 9.0 mm. In this case, the aforementioned bending radius R1 is approximately 1.6 to 49.0 mm, and preferably is approximately 2.3 to 31.0 mm. In a case where the plate thickness is, for example, 30 mm, the aforementioned bending radius R2 is approximately 15 to 90 mm. In this case, the aforementioned bending radius R1 is approximately 16 to 494 mm, and preferably is approximately 23 to 314 mm.
In particular, in a case where the conditions of the above Formulae (1) to (3) are satisfied, surface layer strain becomes less than in the case of the conventional bending method (in which press working is performed in only one step) illustrated in the above described
In addition, in a case where the conditions of the above Formulae (1), (4) and (5) are satisfied, surface layer strain becomes less than in the case of the bending method disclosed in Patent Literature 1 (in which press working is divided into two steps) that is illustrated in the above described
In short, the bending radius R2 of the bend section of the press-formed product is defined within a range of R/t at which there is a risk of cracking occurring at the bend section, in accordance with the plate thickness t of the metal plate. As described above, the range of R/t at which there is a risk of cracking occurring at the bend section is 0.5 to 3.0. In particular, if the metal plate has high ductility, an upper limit of R/t is 2.0. If the metal plate has even higher ductility, the upper limit of R/t is 1.0. Furthermore, the size of the bending radius R1 of the bend section formed in the first step is defined in accordance with the conditions of the above Formulae (1) to (3) based on the aforementioned bending radius R2, and more preferably is defined in accordance with the conditions of the above Formulae (1), (4) and (5). At such time, based on
(b) A press-formed product that is produced by the bending method described in the above (a) has a characteristic plate thickness distribution at the bend section and the vicinity thereof. Specifically, at a cross section, the plate thickness increases as the distance from the vicinity of the top part of the bend section increases, and as a distance from the vicinity of an end of the bend section increases the plate thickness decreases and thereafter increases again, and beyond a position separated by a distance corresponding to 1.5 times the original plate thickness from the position of the end of the bend section, the plate thickness becomes the original plate thickness. Here, the term “vicinity of the top part of the bend section” means one point within a range of ±0.1 mm from the top part. The term “vicinity of an end of the bend section” means one point within a range of ±0.1 mm from an end of the bend section, that is, a boundary between the bend section and a flat section. The term “original plate thickness” means the average plate thickness of the steel plate that is the starting material. The “original plate thickness” corresponds to the average plate thickness of the flat section.
The above described press-formed product is excellent in three-point bending characteristics and axial compressive deformation characteristics. This is because, although in the conventional bending method illustrated in the above described
(c) In the bending method described in the aforementioned (a), as described above, the interior angle θ1 of the bend section of the intermediate formed product formed in the first step is smaller than the interior angle θ2 of the bend section of the press-formed product formed in the second step. Consequently, the intermediate formed product may become unstable on the die assembly when performing press working in the second step. In this case, in the press working in the second step, as the die assembly, it is sufficient for each of the die and the punch to include a pad for restraining the intermediate formed product. The pad that the die includes is called a “die pad”, and the pad that the punch includes is called an “inner pad”.
The present invention was completed based on the above findings. Embodiments of the present invention are described below while referring to the accompanying drawings. Hereunder, first, a press-formed product is described, and thereafter a production method and a production equipment line that are suitable for producing the press-formed product are described.
A press-formed product 20 of the present embodiment is made from a metal plate having a tensile strength of 590 MPa or more. The tensile strength may be 780 MPa or more, may be 980 MPa or more, and may be 1180 MPa or more. A high strength steel plate is suitable as a metal plate having such tensile strength. However, an aluminum plate, a titanium plate, a stainless steel plate, a magnesium plate and the like can also be used as the metal plate. A high strength steel plate having a tensile strength of 1180 MPa or more is preferable as the metal plate.
As shown in
The press-formed product 20 is produced by a production method of the present embodiment that includes press working (bending) that is divided into two steps. The top plate part 21 and the vertical wall part 23a constitute a pair of flat sections, and the upper-side ridge line part 22a connecting these flat sections constitutes a bend section 26. Likewise, the top plate part 21 and the vertical wall part 23b constitute a pair of flat sections, and the upper-side ridge line part 22b connecting these flat sections constitutes a bend section 27. Further, the vertical wall part 23a and the flange part 25a constitute a pair of flat sections, and the lower-side ridge line part 24a connecting these flat sections constitutes a bend section 28. Likewise, the vertical wall part 23b and the flange part 25b constitute a pair of flat sections, and the lower-side ridge line part 24b connecting these flat sections constitutes a bend section 29.
In
As shown in
This plate thickness distribution is obtained by the production method of the present embodiment. In the production method of the present embodiment, the plate thickness is reduced at flat sections (for example: the top plate part 21 and the vertical wall part 23a) around the bend section 26, and by this means a decrease in the plate thickness of the bend section 26 (for example: the upper-side ridge line part 22a) is suppressed. For example, in a case where a press-formed product with a hat-shaped cross section that has the above described plate thickness distribution is a member that is mounted in a vehicle, at a time that the member deforms due to a collision or the like, the upper-side ridge line parts 22a and 22b of the member bear the impact load. In this case, because the plate thickness of the upper-side ridge line parts 22a and 22b that are the bend section 26 is secured, the member is excellent in three-point bending characteristics and axial compressive deformation characteristics.
In the respective press-formed products 20, 2 and 7 of the Inventive Example of the present invention, Comparative Example 1 and Comparative Example 2, the bending radius R2 of the respective bend sections 26, 5 and 8 is 1.5 mm, and the exterior angle A2 of the respective bend sections 26, 5 and 8 is 90°. The bend section 5 of the press-formed product 2 of Comparative Example 1 was formed by press working that was performed in only one step.
The bend section 8 of the press-formed product 7 of Comparative Example 2 was formed by press working that was divided into two steps. Specifically, by press working in a first step, a bend section having a bending radius R1 of 3 mm that is larger than the bending radius R2 of the bend section 8 of the press-formed product 7 was formed, and by press working in a second step, the bend section 8 having a bending radius R2 of 1.5 mm was formed. In other words, the bending radius ratio “R1/R2” was made 2.0. Further, the exterior angle A1 of the bend section formed in the first step and the exterior angle A2 of the bend section formed in the second step were made the same angle of 90°. In other words, an exterior angle ratio “A1/A2” was made 1.0. In short, the press-formed product 7 of Comparative Example 2 was formed according to conditions satisfied only the aforementioned Formulae (2) and (4) among the aforementioned Formulae (1) to (5).
The bend section 26 of the press-formed product 20 of the Inventive Example of the present invention was formed by press working that was divided into two steps. Specifically, by press working in a first step, a bend section having a bending radius R1 of 3 mm that is larger than the bending radius R2 of the bend section 26 of the press-formed product 20 was formed, and by press working in a second step, the bend section 26 having a bending radius R2 of 1.5 mm was formed. In other words, the bending radius ratio “R1/R2” was made 2.0. Further, by the press working in the first step, the bend section was formed to have an exterior angle A1 of 120° that is larger than the exterior angle A2 of the bend section 26 of the press-formed product 20, and by the press working in the second step, the bend section 26 was formed to have an exterior angle A2 of 90°. In other words, the exterior angle ratio “A1/A2” was made 1.33. In short, the press-formed product 20 of the Inventive Example of the present invention was formed according to conditions that satisfied all of the aforementioned Formulae (1) to (5).
As indicated by triangular marks in
In addition, the plate thickness at the top part 26a of the bend section 26 of the press-formed product 20 of the Inventive Example of the present invention is greater than the plate thickness at the top part of the bend section 8 in the press-formed product 7 of Comparative Example 1. Furthermore, a region in which the plate thickness decreases in a flat section at the periphery of the bend section 26 in the press-formed product 20 of the Inventive Example of the present invention is wider than a region in which the plate thickness decreases in a flat section at the periphery of the bend section 8 in the press-formed product 7 of Comparative Example 2.
The reason for the above situation will also be understood from the diagram illustrated in
In addition, as shown in
The plate thickness ratio “t2/t1” for the press-formed product 20 is preferably less than 1.01, and more preferably is 1.00 or more and less than 1.01.
The bending radius of the bend section in the press-formed product of the present embodiment is, for example, a small value of 0 to 3 mm. In addition, the press-formed product has the aforementioned plate thickness distribution. Therefore, the press-formed product is excellent in bending rigidity and torsional rigidity in a case where a static load is placed thereon. Further, in a case where an impact load is applied, buckling that takes the top part of the bend section as an origin is suppressed, and a high initial load and high impact energy absorption amount are obtained. Thus, the press-formed product is excellent in three-point bending characteristics and axial compressive deformation characteristics. Accordingly, the press-formed product of the present embodiment is suitable, for example, as a frame member of an automobile body (for example, a cross member, a side member, a side sill and a pillar), and as various components of an automobile (for example, a door impact beam, a toe-control link and a suspension arm).
Note that, in the case of the press-formed product 20 having a hat-shaped cross section as in the present embodiment, preferably the upper-side ridge line parts 22a and 22b and the lower-side ridge line parts 24a and 24b that are bend sections each have the above described bending radii and plate thickness distribution. However, as long as the performance as a press-formed product is satisfied, a configuration may also be adopted in which any one of the upper-side ridge line parts 22a and 22b and the lower-side ridge line parts 24a and 24b has the above described bending radii and plate thickness distribution.
The press-formed product is not limited to the above described hat-shaped cross section. For example, the press-formed product may have a groove-shaped cross section that does not have flange parts. The press-formed product having a groove-shaped cross section includes a top plate part, two vertical wall parts, and a ridge line part connecting the top plate part and each vertical wall part. In this case, the top plate part and vertical wall parts constitute a pair of flat sections, and the ridge line part connecting these flat sections constitutes a bend section.
[Production Method and Production Equipment Line for Producing Press-Formed Product]
In the present embodiment, the press-formed product is produced by press working that is divided into two steps. In other words, as shown in
As shown in
As illustrated in
As illustrated in
On the other hand, as illustrated in
The radius and angle (exterior angle) of the shoulder part 31a of the first punch 31, and the radius and angle (exterior angle) of the shoulder part 33a of the second punch 33 are set so that the bending radius R1 and interior angle θ1 (exterior angle A1) of the bend section 36c of the intermediate formed product 36 and the bending radius R2 and the interior angle θ2 (exterior angle A2) of the bend section 37c of the press-formed product 37 satisfy the conditions of the above described Formulae (1) to (3) or the above described Formulae (1), (4) and (5).
In the production method of the present embodiment, the press-formed product 37 is produced using the first press apparatus 30 and the second press apparatus 40 that are configured as described above. First, as shown in
In the first forming step, as illustrated in
Next, in the second forming step, as illustrated in
The press-formed product 37 illustrated in
According to the production method of the present embodiment, the plate thickness can be reduced at the flat sections 37a and 37b at the periphery of the bend section 37c, and a decrease in the plate thickness of the bend section 37c can be suppressed. By this means, an occurrence region of surface layer strain that occurs at the bend section 37c is expanded, and the surface layer strain in the bend section decreases. Therefore, according to the production method of the present embodiment, occurrence of cracking at the bend section can be suppressed, and the press-formed product 37 having the bend section 37c that has a smaller bending radius can be produced.
As shown in
In the case of each of the production methods according to the Inventive Example of the present invention, Comparative Example 1 and Comparative Example 2, the bending radius R2 of the bend section of the final press-formed product was made 1.5 mm, and the exterior angle A2 of the bend section was made 90°. In the production method of Comparative Example 1, the bend section was formed by press working in only one step.
In the production method of Comparative Example 2, the bend section was formed by press working that was divided into two steps. In the case of Comparative Example 2, with respect to the bend section formed by press working in the first step (first forming step), the bending radius R1 was changed to various values within a range of values that were greater than the bending radius R2 of the press-formed product while maintaining the exterior angle A1 at the same angle as the exterior angle A2 of the press-formed product.
In the production method of the Inventive Example of the present invention, the bend section was formed by press working that was divided into two steps. In the case of the Inventive Example of the present invention, with respect to the bend section that was formed by press working in the first step (first forming step), the bending radius R1 was changed to various values within a range of values that were greater than the bending radius R2 of the press-formed product, and the exterior angle A1 was also changed to various values within a range of values that were greater than the exterior angle A2 of the press-formed product.
The following facts are indicated by the diagram illustrated in
When the Inventive Examples of the present invention that are indicated by circular marks and Comparative Examples 2 that are indicated by square marks are compared, it is found that when the perimeter ratio “L1/L2” is more than 1.0 and is less than 3.5, surface layer strain in the bend section becomes less than in Comparative Example 2. Here, the perimeter ratio “L1/L2” is represented by the aforementioned Formula (iii). In addition, among the Inventive Examples of the present invention, which are indicated by circular marks, the Inventive Examples in which the surface layer strain is less than in Comparative Example 2 are the Inventive Examples in which the bending radius ratio “R1/R2” is more than 1.5. Accordingly, it is found that when there is a condition that satisfies the aforementioned Formula (5) and also a condition that satisfies the aforementioned Formula (3), surface layer strain becomes less than in Comparative Example 2, and the effect of the Inventive Example of the present invention with respect to cracking is exhibited.
Analysis of the formation of press-formed products having the hat-shaped cross section shown in
As Comparative Example 2, press-formed products Nos. 2, 4 and 6 were formed by the bending method disclosed in Patent Literature 1 that is illustrated in the above described
As the Inventive Example of the present invention, press-formed products Nos. 3, 5 and 7 were formed by the production method of the present embodiment. In each of Nos. 3, 5 and 7, the value of R/t in the press working in the second step was made 1.07, similarly to Comparative Example 2. In the press working in the first step, the value of R/t was made 1.42 for No. 3 that is the same value as for No. 2 of Comparative Example 2, the value of R/t was made 2.14 for No. 5 that is the same value as for No. 4 of Comparative Example 2, and the value of R/t was made 2.85 for No. 7 that is the same value as for No. 6 of Comparative Example 2. In each of Nos. 3, 5 and 7, the exterior angle ratio “A1/A2” was made 1.33.
Further, in each of Nos. 1 to 7, a high strength steel plate having a tensile strength of 1180 MPa-class and a plate thickness of 1.4 mm was used as the metal plate that was the starting material. The specific mechanical properties of the steel plate are as follows:
YP (yield point): 801 MPa
TS (tensile strength): 1197 MPa
El (elongation): 13.6%
The logarithmic strain in the bending direction (circumferential direction of cross section) in the outer surface at the top part of the bend section was determined for each of the press-formed products Nos. 1 to 7. The results are shown in
As shown in
The present invention is not limited to the embodiments described above, and various modifications may be made without departing from the spirit and scope of the present invention.
30 First press apparatus
31 First punch
31
a Shoulder part
32 First die
40 Second press apparatus
33 Second punch
33
a Shoulder part
34 Second die
35 Metal plate
36 Intermediate formed product
36
c Bend section
37 Press-formed product
37
a Flat section
37
b Flat section
37
c Bend section
Number | Date | Country | Kind |
---|---|---|---|
2015-012269 | Jan 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2016/000338 | 1/25/2016 | WO | 00 |