Patent Grant
11383288
This application is based upon and claims the benefit of priority from Japanese patent application No. 2019-11011, filed on Jan. 25, 2019, the disclosure of which is incorporated herein in its entirety by reference.
The present disclosure relates to a method for processing a steel plate and a punching machine.
One of the issues in press-forming of a high tensile strength steel is cracking in a stretch flange. This cracking in a stretch flange occurs due to residual strain on a shear end face. As a method for reducing this residual strain, a heating method is known. As a method for heating a residual strain part, a technique for applying a current and heating a bent part of a press formed product to remove residual strain is known (see, for example, Japanese Unexamined Patent Application Publication No. H07-303919).
There has been a problem that it is difficult to transfer heat to an end part of a steel plate punched in punching processing and residual strain cannot be completely removed or when an end part of a steel plate is heated to such an extent that residual strain can be removed, areas other than the end part are excessively heated, thereby causing a change in the hardness of a part of the steel plate.
The present disclosure provides a method for processing a steel plate capable of removing residual strain at a trim edge thereof without causing overheating in areas of the steel plate other than the trim edge.
In a first example aspect of the present disclosure, a method for processing a steel plate includes: punching a steel plate as a workpiece fixed to a punching die by a punch; making a first heating electrode provided on a punch holder for supporting the punch and a second heating electrode provided on the punching die face each other by maintaining the punch in a state in which the punch penetrates the steel plate and heating a part of the steel plate including a trim edge punched in the punching; and pulling out the punch from the punching die. By disposing the heating electrodes on the punch holder and at a position facing the punch holder in the punching machine, and applying a current to the heating electrodes while the punch is penetrating the steel plate, the trim edge can be sufficiently ended. By heating the part of the steel plate including the trim edge, it is possible to appropriately remove residual strain and avoid overheating of areas other than the part of the steel plate including the trim edge.
The above processing method is effective if it further includes reducing heat generated in the heating and forming a stretch flange at the trim edge. When the stretch flange is formed on the steel plate in a state where the heat is reduced, damage to a flange die can be reduced.
Further, the pulling-out may be started based on a detected temperature of the trim edge. If the punch is pulled out when the temperature reaches an appropriate temperature, the residual strain can be removed appropriately, and softening and hardening of the steel plate can be avoided. Furthermore, relative positions of the punch holder and the punching die are preferably adjusted so that the first heating electrode and the second heating electrode face each other at a bottom dead center of the punch. Such an adjustment eliminates the need for complicated position control of the punch.
Further, each of the heating electrodes may be a coil electrode for generating an induced electromotive force in the steel plate to carry out the heating. The heating in this case includes heating the part of the steel plate without bringing the electrode into contact with a surface of the steel plate. When the steel plate is heated using an induced electromotive force in this manner, damage to the electrodes can be reduced, because the steel plate can be heated without bringing the electrodes into contact with the surface of the steel plate. When induction heating is used in this way, the trim edge can be efficiently heated by the edge effect. Moreover, when an insulator part is provided on a peripheral part of the coil electrode, in the above heating, the insulator part may be brought into contact with the surface of the steel plate to heat the above part of the steel plate. When the insulator part is brought into contact with the surface of the steel plate, it is possible to stably heat the steel plate while preventing damage to the coil electrode.
In a second example aspect of the present disclosure, a punching machine includes: a punch holder including a first heating electrode and configured to hold a punch for punching a steel plate as a workpiece; a punching die including a second heating electrode, the steel plate is being fixed to the punching die; and a current applying control unit configured to apply a current to the first heating electrode and the second heating electrode so that a part of the steel plate including a trim edge punched by the punch is heated when the first heating electrode and the second heating electrode face each other while the punch is penetrating the steel plate. By disposing the heating electrodes on the punch holder and at a position facing the punch holder in the punching machine, and applying a current to the heating electrodes while the punch is penetrating the steel plate, the trim edge can be sufficiently ended. By heating the part of the steel plate including the trim edge, it is possible to appropriately remove residual strain and avoid overheating of areas other than the part of the steel plate including the trim edge.
In a third example aspect of the present disclosure, a method for processing a steel plate includes: punching a steel plate as a workpiece fixed to a punching die by a punch; and heating a part of the steel plate including a trim edge punched in the punching by a first heating electrode provided on a fixing jig for fixing the steel plate to the punching die and a second heating electrode provided on the punching die.
In a fourth example aspect of the present disclosure, a punching machine includes: a punching die including a second heating electrode, a steel plate as a workpiece is being fixed to the punching die; a fixing jig including a first heating electrode and configured to fix the steel plate to the punching die; and an current applying control unit configured to apply a current to the first heating electrode and the second heating electrode so that a part of the steel plate including a trim edge punched by the punch is heated. According to the method for processing a steel plate in the third example aspect and the punching machine in the fourth example aspect, the heating electrodes are disposed on the fixing jig of the steel plate and at a position facing the fixing jig in the punching machine and then the trim edge is heated. Since the part of the steel plate including the trim edge of the steel plate as a workpiece can be heated, it is possible to appropriately remove residual strain and avoid overheating of areas other than the part of the steel plate including the trim edge.
According to the present disclosure, it is possible to provide a method for processing a steel plate capable of removing residual strain at a trim edge thereof without causing overheating in areas of the steel plate other than the trim edge.
The above and other objects, features and advantages of the present disclosure will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not to be considered as limiting the present disclosure.
The punching step includes punching a steel plate 100 fixed to a punching die by a punch 711 that moves forward and backward together with a support shaft 710 of an upper die. As will be described in detail later, the heating step is a step of pressing a punch holder 712 holding the punch 711 against the steel plate 100 and heating a peripheral edge of the hole 110 formed in the punching step. The pulling-out step is a step of pulling out the punch 711 from the punching die after the heating is ended. Note that as shown in the drawing, the area heated in the heating step is a heating area 111 including a trim edge of the hole 110, which area is a part of the steel plate 100.
The cooling step is a step of reducing the heat in the heating area 111 heated in the heating step. Specifically, the steel plate 100 is left for a certain time in a room temperature environment. The stretch flange step is a step of inserting a flange die 900 into the hole 110 and plastically deforming a peripheral edge part of the hole 110 to thereby form a stretch flange 113.
Residual strain generated at the peripheral edge part of the hole 110 in the punching step is removed in the heating step. After the cooling, the steel plate 100 is subjected to the stretch flange step. When the stretch flange is formed on the steel plate 100 in a cooled state, it is possible to reduce the damage to the flange die 900 more than when the stretch flange is formed on the steel plate 100 in a heated state. In particular, in this embodiment, since the steel plate 100 can be sufficiently heated up to the trim edge, the residual strain can be satisfactorily removed. This will be described later. Further, since the heating step can be performed between the punching step and the pulling-out step, an independent heating step of placing the steel plate 100 on a heating apparatus and heating it, which has been necessary in related art, can be omitted. This can shorten the time taken for a series of processing.
The heating temperature at this time is adjusted in such a way that a trim edge 112 becomes 200° C. or higher and lower than the Ac1 point. The residual strain can be appropriately removed when the heating is within this temperature range. In particular, when the steel plate 100 is heated to the Ac1 point or higher, the steel plate 100 undergoes austenite transformation. Thus, the steel plate 100 softens when air-cooled or hardens when rapidly cooled by running water or the like, and then formability in the stretch flange step decreases. Therefore, it is preferable to keep the heating temperature below the Ac1 point.
The punching machine 701 includes, as an upper die, the punch 711, a punch holder 712 including a first heating electrode 713 and detachably supporting the punch 711, and a support shaft 710 that is integrated with the punch holder 712 and moves the attached punch 711 back and forth. Since the first heating electrode 713 is provided on the punch holder 712, the first heating electrode 713 is located substantially near the base of the punch 711. The punching machine 701 further includes, as a lower die, a second heating electrode 723 and a punching die 720 to which the steel plate 100 is fixed. The punching die 720 includes a die hole 721 for retracting the punch 711 and a punched piece at the time of punching. The first heating electrode 713 and the second heating electrode 723 are disposed so as to face each other with the punch 711 penetrating the steel plate 100 and to be brought into contact with the respective surfaces of the steel plate 100.
The punching machine 701 further includes, as a part of the control mechanism, a current applying control unit that applies a current to the first heating electrode 713 and the second heating electrode 723 when the first heating electrode 713 and the second heating electrode 723 are brought into contact with the steel plate 100 and face each other. When a current is applied, the heating area 111 including the trim edge 112 shown in
The first heating electrode 713 may be composed of a plurality of electrodes arranged apart from each other around the punch 711 instead of being an annular electrode surrounding the punch 711 as shown in the drawing. Likewise, the second heating electrode 723 may composed of a plurality of electrodes arranged apart from each other around the die hole 721 instead of being an annular electrode surrounding the die hole 721 as shown in the drawing. In any of these cases, the first heating electrode 713 and the second heating electrode 723 are provided in the vicinity of the punch 711 or the die hole 721 so that the trim edge 112 of the hole 110 to be formed can be sufficiently heated.
The relative positions of the punch holder 712 and the punching die 720 are adjusted in such a way that the first heating electrode 713 and the second heating electrode 723 face each other and are brought into contact with the steel plate 100 at the bottom dead center, which is the lowest end where the punching punch 711 reaches. For example, prior to using the punching machine 701, a user adjusts the relative positions of the punch holder 712 and the punching die 720 by correcting an initial position of the support shaft 710 in the vertical direction according to the thickness of the steel plate 100. Such an adjustment eliminates the need for complicated position control of the punch 711.
A heating time in the heating step may be a preset time or a time until the trim edge 112 reaches a preset temperature. In the latter case, for example, a temperature sensor may be provided between wall surfaces of the second heating electrode 723 and the die hole 721 in the punching die 720 to detect the temperature. The pulling-out step is started after such a heating time has elapsed. When the punch 711 is pulled-out when the temperature reaches an appropriate temperature, the residual strain can be removed appropriately, and the softening and hardening of the steel plate 100 can be avoided.
The pair of heating electrodes shown in the drawing is a coil electrode that applies an alternating current to generate an induced electromotive force in the steel plate 100 to thereby heat the steel plate 100. The pair of heating electrodes is composed of a first heating coil 733 and a second heating coil 743. The first heating coil 733 is surrounded by a first support 735 that is an insulator, and the second heating coil 743 is surrounded by a second support 745 that is an insulator. The heating step is carried out by maintaining the punch 731 in a state in which the punch 731 penetrates the steel plate 100 so that the first heating coil 733 and the second heating coil 743 face each other with the steel plate 100 interposed therebetween and then applying a current to these heating coils.
During the heating, the first support 735 and the second support 745 are brought into contact with the surfaces of the steel plate 100. As a result, the distance between the first heating coil 733 and the second heating coil 743 becomes stable, which makes it easy to control the temperature. Further, since the first heating coil 733 and the second heating coil 743 are not brought into direct contact with the surfaces of the steel plate 100, damage to the electrodes can be reduced. Note that the temperature range for the heating is the same as that for the punching machine 701.
The punching machine 703 includes, as an upper die, the punch 731, a punch holder 732 including the first heating coil 733 supported by the first support 735 and detachably supporting the punch 731, and a support shaft 730 that is integrated with the punch holder 732 and moves the attached punch 731 back and forth. The punching machine 703 further includes, as a lower die, a punching die 740 including the second heating coil 743 supported by the second support 745. The steel plate 100 is fixed to the punching die 740. The punching die 740 includes a die hole 741 for retracting the punch 731 and a punched piece at the time of punching. The first heating coil 733 and the second heating coil 743 are disposed so as to face each other while the punch 731 is penetrating the steel plate 100 and to be brought into contact with the respective surfaces of the steel plate 100.
The punching machine 703 further includes, as a part of the control mechanism, a current applying control unit that applies a current to the first heating coil 733 and the second heating coil 743 when the first heating electrode 733 and the second heating electrode 743 are brought into contact with the steel plate 100 and face each other. When a current is applied, the heating area 111 including the trim edge 112 shown in
The relative positions of the punch holder 732 and the punching die 740 are adjusted in such a way that the first support 735 is brought into contact with the steel plate 100 at the bottom dead center, which is the lowest end where the punching punch 731 reaches. A heating time in the heating step may be adjusted in a manner similar to that for the punching machine 701.
An example of a formed product formed by the above-described processing method will be described.
The punching machine 705 includes a punch 751 as an upper die. The punching machine 705 further includes, as a lower die, a punching die 760 including a second heating electrode 763. The steel plate 100 is fixed to the punching die 760. The steel plate 100 is fixed to the punching die 760 by a fixing jig 752 in which a first heating electrode 753 is embedded. When the steel plate 100 is fixed by the fixing jig 752, the first heating electrode 753 and the second heating electrode 763 are brought into contact with the respective surfaces of the steel plate 100 and face each other.
Further, the punching machine 705 includes, as a part of the control mechanism, a current applying control unit that applies a current to the first heating electrode and the second heating electrode so as to heat a part of the steel plate 100 including a trim edge punched by the punch 751. When a current is applied, a heating area including the trim edge is heated. When the heating area is heated by such an arrangement of the pair of heating electrodes, the trim edge can be sufficiently heated, and the residual strain concentrated on the peripheral part of the trim edge can be satisfactorily removed. Further, since the heating area is a part of the entire steel plate 100, electric power for heating unnecessary areas can be reduced, and overheating that causes softening and hardening can be avoided.
In the processing method in this case, the order of the heating step and the pulling-out step corresponding to
An example of a formed product formed by such a processing method will be described.
From the disclosure thus described, it will be obvious that the embodiments of the disclosure may be varied in many ways. Such variations are not to be regarded as a departure from the spirit and scope of the disclosure, and all such modifications as would be obvious to one skilled in the art are intended for inclusion within the scope of the following claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| JP2019-011011 | Jan 2019 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 20090235715 | Werz | Sep 2009 | A1 |
| 20120111161 | Kuriki | May 2012 | A1 |
| 20170333971 | Denks | Nov 2017 | A1 |
| 20190039109 | Haslmayr | Feb 2019 | A1 |
| 20190091752 | Takishima | Mar 2019 | A1 |
| 20200239974 | Ihara et al. | Jul 2020 | A1 |
| 20200291999 | Mizuta | Sep 2020 | A1 |
| 20210154723 | Shinke | May 2021 | A1 |
| Number | Date | Country |
|---|---|---|
| 3012168 | Jul 2017 | CA |
| 107208170 | Sep 2017 | CN |
| 3212348 | Sep 2018 | EP |
| 7-303919 | Nov 1995 | JM |
| 6-226479 | Aug 1994 | JP |
| 2002-113525 | Apr 2002 | JP |
| 2007-319912 | Dec 2007 | JP |
| 2012-206539 | Oct 2012 | JP |
| Entry |
|---|
| Office Action dated Oct. 27, 2021 in U.S. Appl. No. 16/750,373. |
| ASM International, “Fundamentals of the Heat Treating of Steel”, 2006, ASM International, Practical Heat Treating, 2nd Edition, pp. 9-10 (18 pages total). |
| Office Action dated May 2, 2022 in U.S. Appl. No. 16/750,373. |
| Number | Date | Country | |
|---|---|---|---|
| 20200238360 A1 | Jul 2020 | US |
