This disclosure relates to a sheet material press forming method which makes it possible to stably obtain a target shape while preventing fracture of a metal blank when parts such as automotive parts are manufactured from the metal blank by press forming.
Recently, in view of global environmental issues, high-strength steel sheets have been used frequently as automotive parts for weight reduction of an automotive body.
Further, automotive parts are often manufactured using press forming excellent in terms of manufacturing costs.
However, since high-strength steel sheets have low ductility and easily suffer fractures, compared to low-strength steel sheets, it is not always easy to obtain parts having a target shape by press forming.
Further, strengthening of steel sheets to be used for automotive body weight reduction means thinning of steel sheets, and as the sheet thickness of a steel sheet is made thinner, press wrinkles tend to be caused.
Therefore, the development of a press forming method is strongly required to suppress fractures and press wrinkles.
WO 2017/006793 A (PTL 1) and JP 5867657 B (PTL 2) describe a method in which a preformed shape having no fractures or press wrinkles is manufactured and subsequently subjected to press forming to thereby obtain a product having no fractures or press wrinkles.
PTL 1: WO 2017/006793 A
PTL 2: JP 5867657 B
As a method for suppressing fractures during press forming, it is considered useful to prepare a rough preformed shape as a preforming step and subsequently subject the preformed shape to restrike forming to obtain a target shape.
PTL 1 and PTL 2 each propose a method of preparing a preformed shape for suppressing fractures and subsequently subjecting the preformed shape to restrike forming.
However, since PTL 1 uses the large scale of inflow and rotation of materials in a subsequent process, the method of PTL 1 can be applied only to a fracture risk portion of a flange portion, which has an open periphery and at which a metallic sheet is allowed to move easily.
Further, although PTL 2 indicates the design guideline of a preformed shape in order to suppress forming failure inside a product, PTL 2 merely discusses changing of shapes in cross sections taken by dividing a final shape in a grid pattern or taken radially from the centroid. A metallic sheet is not necessarily deformed in grid-like directions or radially from the centroid during actual restrike forming but deformed three-dimensionally in arbitrary directions. Thus, when a preformed shape is designed without considering this point, it is impossible to control the inflow of the metallic sheet. Further, the method of PTL 2 is markedly labor intensive and time consuming.
This disclosure could thus be helpful to provide a sheet material press forming method in which, considering three-dimensional deformation, press forming is divided into two steps, in which a sheet material is preformed into a shape having the same surface area as a target shape and easy to form in the first step and subsequently formed into the target shape without fractures.
That is, the primary features of this disclosure are as follows.
1. A sheet material press forming method of press forming a formed part having a hat-like cross-sectional shape and including a top portion, a side wall portion, and a flange portion, the top portion having a protrusion with a blockage protrusive shape, from a metal blank, the method comprising:
first, for the top portion in a region of the protrusion, determining, by press forming analysis, a preforming shape which has almost the same surface area as a target shape and is easy to form according to the following steps S1 and S2;
then, press forming the metal blank into the preforming shape, and subsequently crash forming a pertinent portion of the metal blank into a target final shape, where
S1: the region of the protrusion having the target shape is discretized into two-dimensional elements and nodes for finite element analysis, and
S2: a discretized portion is applied with internal stress in normal directions of the two-dimensional elements from the inside of the discretized portion and deformed under the following conditions:
(a) the two-dimensional elements are deformed within an elastic deformation range; and
(b) adjacent ones of the two-dimensional elements have an angle therebetween which is free to change.
According to this disclosure, when a formed part having a hat-like cross-sectional shape and including a top portion, a side wall portion, and a flange portion, the top portion having a protrusion having a protrusive shape with a closed periphery, is formed from a metal blank, it is possible to automatically design an optimal preformed shape by finite element analysis, and as a result, press forming can be performed from a metal blank without causing fractures or press wrinkles.
In the accompanying drawings:
The following describes the present disclosure in detail.
For example, as illustrated in
In order to solve this problem, a method of dividing the press forming process into a plurality of steps is sometimes used. That is, press forming is performed to form a rough shape in a preforming step and press forming is performed again (restrike) in the subsequent step to obtain a target shape. At that time, a shape formed in the preforming step (hereinafter, referred to as “preformed shape”) has been conventionally designed depending on design expert's experience and know-how.
Recently, a design has been made based on the idea of taking, in a preformed shape, product cross sections including fracture regions in a grid pattern or radially from the centroid, deforming the preformed shape, keeping the cross-sectional line lengths of the cross sections in a suitable range to thereby suppress the elongation and contraction of a metallic sheet in the restrike step, which makes it possible to obtain a product without fractures or wrinkles (for example, PTL 2).
However, the metallic sheet during restrike is rarely deformed in the cross sections in a grid-like form or taken radially from the centroid. Typically, the metallic sheet moves three dimensionally in arbitrarily directions almost across the entire region. Therefore, only with the idea of matching the cross-sectional line lengths described in PTL 2, failures such as fractures and wrinkles often occur during the restrike, and trials and errors need to be repeated to determine the shape of the preformed shape. In the worst case, an optimal shape of the preformed shape may not be determined.
Therefore, to deal with three-dimensional deformation of the metallic sheet which cannot be dealt with relying on the idea of using the cross-sectional line length, the inventors conceived of determining an optimal preformed shape by using a three-dimensional finite element method as press forming analysis.
The following describes the concept of this disclosure based on
Then, protrusion regions 1 to 8 to form the target shape are discretized into two-dimensional elements and nodes (making a mesh) as illustrated in
Then, using the finite element method, a rough preformed shape which makes forming of a final shape easy in the subsequent step is determined (
Specifically, internal stress is applied to the discretized portion from the inside in normal directions of the two-dimensional elements (also referred to as “shell elements”) to determine the preformed shape. Important points are (a) the two-dimensional elements should be deformed within an elastic deformation range and (b) an angle between adjacent ones of the the two-dimensional elements should be free to change.
Thus, the rough preformed shape is determined as illustrated in
Next, in actual press forming, a tool of press forming having the preformed shape determined as described above (
Next, specific procedures using the above method will be described.
First, a connection ridge portion between the top portion 11 and the side wall portion 12, including a portion where fractures or wrinkles may occur in the target shape illustrated in
Next, finite element analysis in which the two-dimensional elements constituting the discretized portion are applied with internal pressure from the inside of the discretized portion in normal directions of the two-dimensional elements for deformation is performed. At that time, the analysis is performed under conditions that the two-dimensional elements are deformed within the elastic deformation range and an angle between adjacent two-dimensional elements are free to change.
Thus, the shape of the preformed shape which is easy to form since the shape is rougher than the target shape and has the same surface area as the target shape can be readily obtained. One example of the shape of the preformed shape thus obtained is illustrated in
The preformed shape thus obtained has a rougher shape than the target shape and can avoid local deformation and stress concentration, and thus, it is free from fractures or wrinkles. Further, when the preformed shape is crash formed into the target shape, bending deformation is only applied to the two-dimensional elements and nodes in the crash forming, and thus the two-dimensional elements are less easily deformed. Accordingly, the preformed shape can be obtained without fractures or wrinkles, and when the preformed shape is press formed into the target shape, additional elongation or contraction will not occur. Thus, the target shape can be eventually obtained without fractures or wrinkles.
A part having a shape illustrated in
A method having only one step of draw forming was used as a conventional method (conventional method 1).
A method having a first step of shallow draw forming and a second step of crash forming with pad as illustrated in
The disclosed method had a first step of draw forming and a second step of crash forming (disclosed method 1).
First, a forming result of the conventional method 1 is illustrated in
Further, using the comparative method 1, a result of shallow draw forming of the preformed shape is illustrated in
Next, in performing the disclosed method 1, the preformed shape was subjected to press forming analysis by the finite element method. As illustrated in
Furthermore, a result of crash forming, as the second step, using a tool of press forming having the target shape is illustrated in
A part having a shape illustrated in
As in Example 1, a method having only one step of draw forming was used as a conventional method (conventional method 2).
A method having a first step of shallow draw forming and a second step of crash forming with pad was used as a comparative method (comparative method 2).
The disclosed method had a first step of draw forming and a second step of crash forming (disclosed method 2).
First, a forming result of the conventional method 2 is illustrated in
As illustrated in
Further, using the comparative method 2, a result of shallow draw forming is illustrated in
Next, in performing the disclosed method 2, the preformed shape was subjected to press forming analysis by the finite element method. As illustrated in
Furthermore, a result of crash forming using a tool of draw forming having the target shape as the second step is illustrated in
Number | Date | Country | Kind |
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JP2017-220224 | Nov 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/033855 | 9/12/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/097829 | 5/23/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
9921572 | Dos Reis Alipio da Cruz | Mar 2018 | B2 |
20090272171 | Golovashchenko | Nov 2009 | A1 |
20120059865 | Shao | Mar 2012 | A1 |
20160160311 | Nakagawa et al. | Jun 2016 | A1 |
20180185899 | Saito et al. | Jul 2018 | A1 |
Number | Date | Country |
---|---|---|
2006139447 | Jun 2006 | JP |
2006185228 | Jul 2006 | JP |
2008006464 | Jan 2008 | JP |
2015139782 | Aug 2015 | JP |
5867657 | Feb 2016 | JP |
2017006793 | Jan 2017 | WO |
Entry |
---|
Dec. 11, 2018, International Search Report issued in the International Patent Application No. PCT/JP2018/033855. |
Mar. 15, 2021, Office Action issued by the Korean Intellectual Property Office in the corresponding Korean Patent Application No. 10-2020-7013738 with English language concise statement of relevance. |
Nov. 2, 2021, Office Action issued by the China National Intellectual Property Administration in the corresponding Chinese Patent Application No. 201880073714.1 with English language search report. |
Number | Date | Country | |
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20200316667 A1 | Oct 2020 | US |