Patent Application
20210078063
The technology disclosed herein relates to a hot press processing method and a hot press processing apparatus.
As a hot press processing method of the present type, a method of obtaining a molded article placed in a quenched state by heating and press-molding a workpiece and then cooling the workpiece in molding dies has been commonly known.
As one example of the hot press processing method (hot press molding method) as above, Patent Literature 1 discloses a feature of press-molding a workpiece (metal plate material) disposed between molding dies (an upper die and a lower die) and then quenching the workpiece by a direct-cooling method in which the surface of the workpiece in a pressed state is cooled by being brought into contact with coolant.
Patent Literature 1: International Publication No. WO 2012/161192
When a general hot press processing method is used, the thermal contraction occurs in the workpiece in accordance with the cooling before and after the removal from the dies. Meanwhile, when the quenching as that described in Patent Literature 1 is performed before the removal of the workpiece from the dies, the volume of the workpiece expands due to organization change in accordance with so-called martensitic transformation.
The thermal contraction in accordance with the cooling and the volume expansion in accordance with the transformation uniformly progress when so-called die cooling is used. However, when the direct-cooling method as that described in Patent Literature 1 is employed, the temperature distribution of the workpiece may be uneven. In other words, while the cooling abruptly progresses in sections with which the coolant is brought into direct contact, the cooling progresses relatively gradually in other sections. As a result, sections of which temperature is relatively high and sections of which temperature is low are mixed in the workpiece.
Due to the unevenness as above, the thermal contraction and the volume expansion progress at different speeds in each portion of the workpiece and diminish each other. As a result, when the workpiece is released from the molding dies, there is a fear that the workpiece may be deformed due to the residual stress thereof. The deformation as above unintentionally occurs and is desired to be suppressed as much as possible in order to enhance the processing accuracy of the molded article.
The technology disclosed herein has been made in view of the abovementioned points, and an object thereof is to enhance the processing accuracy of a molded article when quenching is performed by a direct-cooling method.
As a result of intensive studies, the inventors of the present application have focused on intentionally releasing the residual stress in, out of the sections in which the accuracy of the molded article is to be guaranteed and other sections, the latter sections and have found the present disclosure.
Specifically, the technology disclosed herein is according to a hot press processing method for processing a workpiece into a molded article. The hot press processing method includes: a heating step of heating the workpiece; a pressing step of press-molding, by molding dies, the workpiece heated in the heating step after loading the workpiece between the molding dies; and a cooling step of bringing coolant into contact with a front surface of the workpiece that is molded and placed in a pressed state by the pressing step, to thereby cool the workpiece and place the workpiece in a quenched state. In the hot press processing method, the workpiece molded and placed in the pressed state by the pressing step forms gaps with respect to the molding dies so as to allow deformation at time of the cooling step except for a predetermined section in the workpiece.
According to this method, the workpiece is cooled and placed in a quenched state in a state in which the gaps are formed with respect to the molding dies except for the predetermined section serving as the section in which accuracy is to be guaranteed. As a result, deformation is allowed in the section in which the gaps are formed with respect to the molding dies, and hence deformation due to the residual stress may occur in the section in which the gaps are formed.
The deformation due to the residual stress is suppressed in the abovementioned predetermined section when the workpiece is released from the molding dies by the amount by which the residual stress is released in the section in which the gaps are formed. As described above, the section (predetermined section) in which accuracy is to be guaranteed and the section in which deformation caused by the residual stress is allowed are used separately, and the residual stress is intentionally released in the latter section. As a result, unintentional deformation can be suppressed in the former section, and the processing accuracy of the molded article can be enhanced.
The predetermined section may form a section in contact with another member different from the molded article.
In general, a high processing accuracy is required in sections in contact with different members such as a section on which another member is mounted and a section joined to another member as compared to other sections. The abovementioned method can meet such needs.
The predetermined section may be provided in a plurality of places in the workpiece, and the gaps may be provided between the predetermined sections.
A dimension of each of the gaps in a direction along the workpiece may be set to 10 mm or more.
As a result of intensive studies, the inventors of the present application have found that the deformation in the section in which the residual stress is to be released is effectively realized when the dimension of each of the gaps is set to 10 mm or more.
In other words, when the dimension of the gap is set to less than 10 mm, the sections in which accuracy is to be guaranteed come close to each other. As a result, the workpiece is restricted by those sections, and the deformation for releasing the residual stress becomes insufficient.
Meanwhile, when the dimension of the gap is set to 10 mm or more, the sections in which accuracy is to be guaranteed are sufficiently spaced apart from each other, and hence the deformation for releasing the residual stress is sufficiently allowed without restricting the workpiece by those sections.
The molded article may be a vehicle component of an automobile.
The molded article may be a framework component of the automobile.
The molded article may be a pillar member of the automobile.
Another technology disclosed herein is according to a hot press processing apparatus for processing a workpiece into a molded article. The hot press processing apparatus executes: a heating step of heating the workpiece; a pressing step of press-molding, by molding dies, the workpiece heated in the heating step after loading the workpiece between the molding dies; and a cooling step of bringing coolant into contact with a front surface of the workpiece that is molded and placed in a pressed state by the pressing step, to thereby cool the workpiece and place the workpiece in a quenched state. In the hot press processing apparatus, the workpiece molded and placed in the pressed state by the pressing step forms gaps with respect to the molding dies so as to allow deformation at time of the cooling step except for a predetermined section in the workpiece.
According to this configuration, the workpiece is cooled and placed in a quenched state in a state in which the gaps are formed with respect to the molding dies expect for the predetermined section serving as the section in which accuracy is to be guaranteed. As a result, the deformation is allowed in the section in which the gaps are formed with respect to the molding dies, and hence deformation due to the residual stress occurs in the section in which the gaps are formed.
The deformation due to the residual stress is suppressed in the abovementioned predetermined section when the workpiece is released from the molding dies by the amount by which the residual stress is released in the section in which deformation is allowed. As described above, the section in which accuracy is to be guaranteed and the section in which is not to be guaranteed are used separately, and the residual stress is intentionally released in the latter section. As a result, unintentional deformation can be suppressed in the former section, and the processing accuracy of the molded article can be enhanced.
As described above, the technology disclosed herein is capable of enhancing the processing accuracy of the molded article when the quenching is performed by the direct-cooling method.
Embodiments of the present invention are described with reference to the drawings. The description below is an example.
The press-molded article according to this embodiment is a pillar member 100 that serves as a vehicle component of an automobile. The cross-sectional shape of the pillar member 100 is a hat-shaped profile. Specifically, the pillar member 100 is a center pillar installed between a floor panel and a roof panel of the automobile. In other words, the pillar member 100 is formed to have a long plate shape with a narrow width and is mounted in a posture in which the longitudinal direction is along the vehicle up-down direction when the vehicle is assembled.
In the pillar member 100, a section in which a relatively high processing accuracy is desired, in other words, a section (predetermined section) in which accuracy is to be guaranteed exists. The section is hereinafter referred to as an “accuracy-guaranteed section” and is denoted by reference character “Wr”. As illustrated in hatching portions in
As illustrated in
The lower die 12 includes a protruding molding surface 16 protruding upward. The upper die 11 includes a recessed molding surface 15 corresponding to the protruding molding surface 16 of the lower die 12. Cross sections illustrated in
As described above, the plurality of accuracy-guaranteed sections Wr are provided in the pillar member 100. Thus, the recessed molding surface 15 includes first molding surfaces 15a for molding the accuracy-guaranteed sections Wr, and second molding surfaces 15b for molding sections other than those sections (hereinafter referred to as “deformation-allowed sections” and denoted by reference character “Wd”).
Similarly, the protruding molding surface 16 includes first molding surfaces 16a for molding the accuracy-guaranteed sections Wr, and second molding surfaces 16b for molding the deformation-allowed sections Wd. The first molding surfaces 16a and the second molding surfaces 16b of the protruding molding surface 16 are provided in places corresponding to the first molding surfaces 15a and the second molding surfaces 15b of the recessed molding surface 15.
The configuration of the first molding surfaces 16a and the second molding surfaces 16b in the protruding molding surface 16 is described below, but the description below is common to the first molding surfaces 15a and the second molding surfaces 15b in the recessed molding surface 15.
The first molding surfaces 16a and the second molding surfaces 16b are provided across a plurality of places. As illustrated in
As illustrated in
The total area of the second molding surfaces 16b provided across a plurality of places is set to be from 50% to 80% of the area of the entire protruding molding surface 16. A dimension (substantially the interval between the first molding surfaces 15a as illustrated in
In the upper die 11 and the lower die 12, coolant passages 17 and 18 from which liquid coolant (cold water in this embodiment) is supplied for cooling the workpiece W in the pressed state are provided. The hot press processing apparatus 1 according to this embodiment employs a direct-cooling method in which cold water is sprayed on the workpiece W in the pressed state. In order to carry out the direct-cooling method, the coolant passages 17 are opened in the recessed molding surface 15 and are preferably opened in the second molding surfaces 15b of the recessed molding surface 15. Similarly, the coolant passages 18 are opened in the protruding molding surface 16 and preferably opened in the second molding surface 16b of the protruding molding surface 16.
As illustrated in
The workpiece W is molded by hot stamping in which the workpiece W is press-molded and is then cooled in the pressed state. In other words, the protruding molding surface 16 and the recessed molding surface 15 plastically deform the workpiece W when descending toward the upper die 11 and the lower die 12, to thereby form the cross-sectional shape having a hat-shaped profile.
When the workpiece W is in the pressed state, the first molding surfaces 15a and 16a for molding the accuracy-guaranteed sections Wr approach or come into contact with the workpiece W (see the circled portions in
A hot press processing method using the hot press processing apparatus 1 is described in detail below.
First, the flat-plate-shaped workpiece W is heated and is heated to the Ac3 point or more. As a result, the transformation of the workpiece W to austenite is completed.
As illustrated in
As illustrated in
In a state in which the workpiece W is molded and is placed in a pressed state by the upper die 11 and the lower die 12, cold water is caused to flow through the coolant passages 17 in the upper die 11 and the coolant passages 18 in the lower die 12. The cold water comes into contact with the front surface of the workpiece W in the pressed state through openings provided in the recessed molding surface 15 and the protruding molding surface 16. The cold water that has come into contact with the front surface of the workpiece W cools the workpiece W to a point that is less than the Ms point. As a result, martensitic transformation of the workpiece W is performed, and the workpiece W is placed in a quenched state.
Although illustration is omitted, the upper die 11 is caused to ascend, and the press-molded workpiece W is removed from the die. The workpiece W removed from the die is carried out from the lower die 12.
The workpiece W carried out from the lower die 12 is air-cooled by the atmosphere. As a result, the quenched workpiece W is cooled in a manner that is more gradual as compared to the water cooling performed by the cold water and reaches a normal temperature.
Incidentally, in the workpiece W before and after being removed from the dies, thermal contraction occurs in accordance with the water cooling and the air cooling. Meanwhile, when quenching as described above is performed before the removal of the workpiece W from the dies, the volume of the workpiece W expands due to organization change in accordance with martensitic transformation.
The thermal contraction in accordance with the cooling and the volume expansion in accordance with the transformation uniformly progress when so-called die cooling is used. However, when the direct-cooling method described above is employed, the temperature distribution of the workpiece W may be uneven. In other words, while the cooling abruptly progresses in the sections with which cold water is brought into direct contact such as sections facing the openings of the coolant passages 17 and 18, the cooling progresses relatively gradually in sections other than those sections. As a result, sections of which temperature is relatively high and sections of which temperature is low are mixed in the workpiece W.
Due to the unevenness as above, the thermal contraction and the volume expansion progress at different speeds in each portion of the workpiece W and diminish each other. As a result, when the workpiece W is released from the molding dies, there is a fear that the workpiece W may be deformed due to the residual stress thereof. The deformation as above unintentionally occurs and is desired to be suppressed as much as possible in order to enhance the processing accuracy of the pillar member 100.
Thus, in this embodiment, the workpiece W in the pressed state forms the gaps c2 with respect to both of the upper die 11 and the lower die 12 so as to allow deformation at the time of water cooling except for the accuracy-guaranteed sections Wr in the workpiece.
In other words, as described above, the workpiece W is cooled and placed in a quenched state in a state in which the gaps c2 are formed with respect to the upper die 11 and the lower die 12 except for the accuracy-guaranteed sections Wr serving as sections in which accuracy is to be guaranteed. As a result, deformation is allowed in sections in which the gaps c2 are formed with respect to the upper die 11 and the lower die 12, in other words, in the deformation-allowed sections Wd, and hence deformation due to the residual stress occurs in the deformation-allowed sections Wd.
Then, the deformation due to the residual stress is suppressed in the accuracy-guaranteed sections Wr when the workpiece W is removed from the upper die 11 and the lower die 12 by the amount by which the residual stress is released in the deformation-allowed sections Wd. As described above, the sections (accuracy-guaranteed sections Wr) in which accuracy is to be guaranteed and the sections (deformation-allowed sections Wd) in which deformation caused by the residual stress is allowed are used separately, and the residual stress is intentionally released in the latter sections. As a result, unintentional deformation can be suppressed in the former sections, and the processing accuracy of the pillar member 100 serving as the molded article can be enhanced.
In the deformation-allowed sections Wd, the pressure applied when the workpiece W is press-molded can be reduced by the amount by which the gaps c2 are provided. As a result, when the press molding is performed, the load on the hot press processing apparatus 1 is reduced.
The processing accuracy is not desired in the deformation-allowed sections Wd as much as in the accuracy-guaranteed sections Wr in the first place. By providing sections as above across a plurality of places, the processing of the workpiece W becomes easier.
Sections corresponding to the ridges of the pillar member 100 have a higher rigidity than other sections. Therefore, the deformation in parts corresponding to the ridges affects the processing accuracy of the entire pillar member 100. Therefore, by causing the sections corresponding to the ridges of the pillar member 100 to be the accuracy-guaranteed sections Wr, the processing accuracy of the entire pillar member 100 can be secured.
The dimension of the gap c2 in the direction along the front surface of the workpiece W, in other words, the dimension d of the second molding surfaces 15b and 16b is set to 10 mm or more as described above.
As a result of intensive studies, the inventors of the present application have found that the deformation in the deformation-allowed section Wd is effectively realized when the dimension d of the second molding surfaces 15b and 16b is set to 10 mm or more.
In other words, when the dimension d of the second molding surfaces 15b and 16b is set to less than 10 mm, the accuracy-guaranteed sections Wr in addition to the first molding surfaces 15a and 16a come relatively close to each other. As a result, the workpiece W is restricted by the accuracy-guaranteed sections Wr, and the deformation in the deformation-allowed sections Wd becomes insufficient.
Meanwhile, when the dimension d of the second molding surfaces 15b and 16b is set to 10 mm or more, the accuracy-guaranteed sections Wr are sufficiently spaced apart from each other. As a result, the deformation for releasing the residual stress is sufficiently allowed without restricting the workpiece by the accuracy-guaranteed sections Wr.
In the abovementioned embodiment, as one example of the molded article, the pillar member has been described as the vehicle component of the automobile, but the technology disclosed herein can also be applied to a framework component of the automobile such as a side frame. Even in this case, unintentional deformation can be suppressed, and the processing accuracy of the molded article can be enhanced.
In the abovementioned embodiment, a configuration in which air cooling is performed by the atmosphere after the die removal step has been described, but the present invention is not limited to this configuration. For example, slow cooling may be performed in the die.
1 Hot press processing apparatus
11 Upper die (molding die)
12 Lower die (molding die)
15 Recessed molding surface
15
a First molding surface
15
b Second molding surface
16 Protruding molding surface
16
a First molding surface
16
b Second molding surface
17 Coolant passage
18 Coolant passage
100 Pillar member
c2 Gap
W Workpiece
Wr Accuracy-guaranteed section (predetermined section)
Wd Deformation-allowed section (section besides predetermined section)
| Number | Date | Country | Kind |
|---|---|---|---|
| 2018-066820 | Mar 2018 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2019/005309 | 2/14/2019 | WO | 00 |
