TWI554343B - Press forming die and producing method of pressed products - Google Patents

Description

Press forming mold and method for manufacturing press molded product Field of invention

The present invention relates to a method for producing a press-formed article which is obtained by using a press-forming mold for a metal sheet and the press-molding mold to press a mold. In particular, the present invention relates to a press-forming mold and a method for producing a press-formed product, which are used for reducing the rebound generated after press forming and ensuring good shape freezeability.

Background of the invention

A member of various shapes can be formed by press forming using a metal plate such as a steel plate or an aluminum alloy plate. Therefore, a press-formed product is widely used in a vehicle member for an automobile or the like.

In the press-formed product, poor dimensional accuracy (poor shape freezing) is a problem, and this dimensional accuracy is called rebound after the press forming of the metal sheet, because the angle of the press-formed product changes or rises. And the initiator.

This rebound is caused by the residual stress introduced into the metal sheet during press forming, and is elastically deformed by the press-formed product after the press forming is completed. The residual stress introduced into the metal sheet is on the sheet of the metal sheet When the thickness direction or the in-plane direction is uneven, it is easy to rebound.

In order to reduce the rebound and improve the dimensional accuracy of the press-formed product, it is quite effective to increase the pressing force for the blank in the press forming at the end of the press forming.

However, in order to increase the pressing force during the press forming, it is generally necessary to provide a press forming apparatus using a variable mold pad device such as a servo valve.

In the above-mentioned problem, Patent Document 1 discloses a press molding die in which an elastic body such as a spring is placed in a press molding die. In the press-molding mold, even if the variable mold pad device is not provided, the pressing force can be increased at the end of press forming.

Patent Document 2 discloses a press-molding mold in which a spring disposed in a press-molding mold is a circular spring. In the press molding die, by using a circular spring which can generate a high load even with a low stroke, even if the variable die pad device is not provided, the increased pressing force can be made more at the end of press forming. Big.

Patent Document 3 discloses a press-molding mold in which a die is divided into a corner end portion and a straight side portion. In the press forming mold, the pressing force can be increased or decreased at each press forming portion.

[Advanced technical literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open Publication No. 2002-321013

[Patent Document 2] Japanese Patent Laid-Open Publication No. 2004-344925

[Patent Document 3] Japanese Patent Laid-Open Publication No. 2003-94119

Summary of invention

In the press molding die disclosed in Patent Document 1, even if the portion where the pressing force is to be increased is a part of the entire press portion, it is necessary to increase the pressing force of the entire press portion. That is, in order to suppress the rebound of the press-formed product, it is necessary to make the spring of the press-forming mold larger or to increase the number of springs. However, there are limitations in the arrangement of springs in the press forming mold. Therefore, when a metal sheet having a large rebound strength such as a high-tensile steel or a high-strength aluminum alloy is used as a blank for press forming, it is quite difficult to sufficiently increase the pressing force.

In the press-molding mold disclosed in Patent Document 2, a circular spring that can obtain a high load-bearing reaction force with a low stroke is used for the spring for increasing the pressing force. Therefore, it is possible to effectively increase the pressing force with a small stroke at the end of the press forming in which the pressing force must be increased. However, similarly, in the press-molding mold, even if the portion where the pressing force is to be increased is a part of the entire press portion, it is necessary to increase the pressing force of the entire press portion. Therefore, when a metal sheet having a higher strength and more progress has been pressed and formed as a blank in recent years, even if a circular spring is used, the increase in the pressing force is insufficient.

In the press-molding mold disclosed in Patent Document 3, in order to suppress the occurrence of buckling (rebound) at the end portion of the press-formed product which becomes the contraction flange deformation region, the pressing force at the initial stage of press forming is increased. Further, in order to avoid the occurrence of cracking at the corner end portion, the pressing force in press forming is reduced. also, In order to prevent the shape of the corner end from being frozen, the pressing force is increased again before the valve closing point (press forming end point) of the press forming. However, in the press-molding mold, the press mold is divided into a type in order to change the pressing force of a part of the entire portion of the press portion. By making the press mold a split type, it is only necessary to increase the pressing force of the necessary region without requiring a large spring force. However, in general, when the split mold is compared with the integrated mold, there are many problems related to the manufacture, maintenance management, repair exchange, and life of the mold. Therefore, the use of the split mold makes the management of the manufacturing process of the press-formed product complicated, and the manufacturing cost of the press-formed product increases. Therefore, in the mass production step of press-molding a member for an automobile vehicle or the like, it is strongly desired to use a press mold of a non-divided type to change the pressing force of a part of the entire portion of the press portion. On the other hand, the so-called integral press mold means a press die which is formed by the minimum number of parts which are not easily divided into the above, from the viewpoint of the structure of the press mold and the shape of the press-formed product.

Further, the press-molding mold disclosed in Patent Document 3 is a press-molding mold for press working of a metal plate, and is not suitable for pressing a high-strength metal plate. Specifically, in the press forming mold disclosed in Patent Document 3, the steel sheet is mainly extruded into a deep cylindrical shape. Therefore, the shape of the press-formed product obtained by the press-molding mold is different from that of the press-formed product in which the high-strength metal sheet is mainly formed by press-forming. In the press forming of a high-strength metal sheet as a blank, a press bending process is often used, and the press bending process is used to obtain a press-formed product having a shape in which both ends in the longitudinal direction are open (section hat shape). By. When the high-strength metal sheet is pressed and bent, the sheet metal is extruded into a deep Different problems arise in the case of a cylinder.

In the extrusion process in which the metal sheet is formed into a deep cylindrical shape, the extruded corner end portion of the press-formed product becomes a contraction flange deformation region. On the other hand, in the case of forming a high-strength metal sheet into a shape in which the both ends in the longitudinal direction are open (for example, a member member), a portion of the end portion of the press-formed article (for example, a convex portion located inside the bent portion) is formed. The edge portion will become the extended flange deformation region. Here, the deformation of the contraction flange means a deformation which occurs at the same time as the two-axis extension and contraction in the sheet surface, and the deformation of the extension flange means that the two shafts in the sheet surface are deformed together. In other words, the press-formed product extruded by the press-molding mold disclosed in Patent Document 3 does not exist as a corner end portion of the member member or the like which becomes a deformed region of the extended flange. Further, in the press-formed press-formed product, the thickness of the flange portion which is caused by the deformation of the shrinkage flange will not change or increase. On the other hand, in the press-formed product subjected to the extrusion bending process, the thickness of the flange portion which is caused by the deformation of the extended flange is remarkably reduced. In the region where the thickness of the sheet is remarkably reduced during press forming, it is difficult to convey the pressing force to the blank, and as a result, the dimensional accuracy of the wall called the press-formed product or the wave of the vertical wall is likely to be poor. Here, the so-called extrusion processing means a press forming (machining) which is free from the region where the extended flange is deformed, and which can be obtained without opening at both ends perpendicular to the direction (pressing direction) of the punching machine. A container-shaped (cylindrical) press-formed product of a part. Further, the so-called extrusion bending process means a press forming (machining), and the press forming has a region where the extended flange is deformed, and can be obtained in the longitudinal direction (the flange portion to which the pressing force is applied is extended) The direction of the member is a press-formed product having an opening at both ends. Pressing a high-strength metal sheet into a component member In the manufacturing steps, etc., it is strongly desired to develop a press-molding mold which can suppress the rebound in addition to the region where the contraction flange is deformed, in the portion where the stretched flange is deformed.

In view of the above-described circumstances, an object of the present invention is to provide a press-molding mold and a method for producing a press-formed product which is press-formed using the press-molding mold, and the mold-based press mold is non-divided and integrated, and even The high-strength metal sheet is press-formed as a blank, and the springback at the portion which becomes the deformation region of the extended flange can also be suppressed. That is, the object of the present invention is to provide a press forming mold and a method for producing a press-formed product, which are easy to use without using a press forming apparatus having a variable mold pad device, and which is easy to use. When the metal sheet produced by the rebound of the high-tensile steel or the high-strength aluminum alloy is pressed and formed as a blank, the dimensional accuracy is high by sufficiently increasing the pressing force for the blank at the end of the press forming. The person who suppresses the molded product. In particular, it is an object of the present invention to provide a press-molding mold and a method for producing the press-formed product thereof, which are used in a press-molding mold which presses and bends a metal sheet, and which can be used in addition to a contraction flange deformation region with high dimensional accuracy. There is also a press-formed product which extends the deformed region of the flange to press the former.

The present inventors have made a review on a die-formed product having a stretched flange-deformed region such as a component member, and it is possible to effectively increase the pressurizing force in a portion where it is necessary to increase the pressing force. As a result, it was found that a part of the press mold of the press forming mold was subjected to The pressing portion is in the case where a pressing force increasing portion is provided in a part of the punching mold of the press forming mold. According to this configuration, at the end of the press forming, the pressure receiving portion is brought into contact with the pressing force increasing portion, and the pressing die is elastically deformed and deflected, whereby the portion where the pressing force of the blank is to be increased can be increased. , locally add the pressing force. Further, the rebound of the press-formed product having the extended flange deformation region of the member member or the like can be greatly reduced. Here, the component having the extended flange deformation region of the member member or the like refers to a press-formed product in which both ends in the longitudinal direction are open-section hat-shaped.

The gist of the present invention is as follows.

(1) One aspect of the present invention is a press forming mold comprising: a punching die having a punching portion and a die plate portion for transferring a shape to a blank; a rigid die paired with the punching die And the pressing die has a first surface that faces the template portion and is in contact with the template portion at the end of press forming, faces the rigid die, and is sandwiched with the rigid die Holding a second surface of the blank and a third surface connecting the first surface and the second surface and facing the punching portion, and the pressing die is between the third surface and the punching portion And the press-forming mold is characterized in that: the pressure-receiving portion includes a groove portion on the first surface of the press mold; and the pressing force-adding portion is formed in the template portion and the first surface The facing surface is protruded toward the pressure receiving portion and is pressed in the pressing direction at the end of press forming to cause a reaction force in the opposite direction.

(2) The press-molding mold according to the above (1), wherein the pressure-receiving portion and the pressing force-adding portion are removed from the press-molding mold In the case of the area where the thickness of the flange portion of the press-formed product is the largest, the maximum thickness of the portion of the press-formed product is greater than 0% and 97% or less of the thickness of the largest portion of the thickness of the molded article. When the thickness reduction portion is formed, when viewed in the pressing direction, the pressure receiving portion overlaps with a portion of the corresponding region of the thickness reduction portion of the blank.

(3) The press-molding mold according to the above aspect (1), wherein the pressure receiving portion is formed by the groove portion, and the meat thickness of the press die at the groove portion position is regarded as L in units of mm, and is removed. When the minimum thickness of the die of the die at the position where the groove is in contact with the blank is expressed in units of mm, the press die may satisfy the following formula A or formula B, and the pressurizing force is added. The protruding height is expressed as G in the unit mm, and the pressing stroke distance from the press forming start point to the end of the press forming is regarded as PS in units of mm, and the aforementioned protruding height G of the pressing force applying portion satisfies the following formula C.

40≦H≦50, 20≦L≦0.8×H. . . (Formula A)

50<H≦80, 20≦L≦40. . . (Formula B)

0.02×PS+H-L≦G≦0.3×PS+H-L. . . (Formula C)

(4) The press-molding mold according to the above (1) or (2), wherein a part of the boundary between the pressure receiving portions is defined as the groove portion.

(5) The press-molding mold according to any one of the above aspects, wherein the pressurizing force applying portion may have an elastic body that imparts the reaction force.

(6) The press-molding mold according to any one of (1) to (5), wherein the elastic body may be a circular spring, a coil spring, or a rubber. At least one of them.

(7) The method for producing a press-molded article according to any one of the above aspects (1) to (6), comprising: pressing the blank when the press forming is performed When the forming start position of the stroke is regarded as 100%, and the forming end position of the pressing stroke is regarded as 0%, the press forming at the position from the pressing stroke of 2% or more and 30% or less to the forming end position is completed. A step of adding a pressing force to a part of the aforementioned blank in the press forming.

According to the above aspect of the invention, the pressure receiving portion is provided in one portion of the press mold, and the pressing force increasing portion is provided in one of the punch mold portions. The pressure receiving portion and the pressing force increasing portion are in contact at the end of press forming, and the die is elastically deformed. As a result, the pressing force from the pressing force increasing portion can be sufficiently conveyed at the end of the press forming at the portion of the blank where the pressing force is required to be increased. That is, even if the press-formed product has an extended flange deformation region in addition to the contraction flange deformation region, the rebound of the press-formed product can be effectively reduced.

In addition, a press-formed product which is press-formed by using a conventional press-molding mold in which the pressure-receiving portion and the pressing force-increasing portion are removed from the press-molding mold, and a portion in which the thickness of the flange portion is thinned is used as a plate. In the thickness reduction portion, according to the aspect of the invention, a part of the region corresponding to the thickness reduction portion of the blank (the portion where the pressing force is required to be increased) and the pressure receiving portion are observed along the pressing direction. overlapping. Therefore, the pressing force at the portion where the pressing force is required to be increased is appropriately increased at the end of the press forming. Its knot As a result, even if the press-formed product has an extended flange deformation region in addition to the contraction flange deformation region, the rebound of the press-formed product can be further reduced.

Further, according to the above aspect of the present invention, a metal sheet which is easily rebounded by a high-tensile steel or a high-strength aluminum alloy or the like is used as a blank, and a general press forming apparatus which does not have a variable mold pad device is used. The press-molding mold of one type of the split type has a stretched flange deformed region in addition to the contracted flange deformation region, and a press-formed product having high dimensional accuracy can be obtained.

1~4, 91‧‧‧ Press forming mold

5‧‧‧毛毛

6a‧‧‧Bending outer part (maximum thickness)

6b‧‧‧Bending inner part (thickness reduction part)

6c~6f‧‧‧ Straight line

10‧‧‧punch mould

12‧‧‧ Punch Department

13‧‧‧Front end face of punching machine 12

14‧‧‧ Template Department

16a~16f‧‧‧Pressure force increase section (round spring unit)

18‧‧‧ 垫部

20‧‧‧Molding

25a~25f‧‧‧Pressure mould

30a, 30b, 30g~30j‧‧‧ Pressure part (groove)

30c, 30d‧‧‧ Pressure Department

31a~31f‧‧‧ first side

32a~32f‧‧‧ second side

33a, 33b‧‧‧ third side (side)

35c, 35d‧‧‧ditch

40a‧‧‧Latch

42a‧‧‧round spring (elastomer)

50‧‧‧Pressure molded products

51a, 51b‧‧‧ Straight side

52‧‧‧Bend

54a, 54a’, 54b, 54b’‧‧‧Flange

55a, 55a’, 55b, 55b’‧‧‧ vertical wall

55c‧‧‧ top

57‧‧‧Finished products after finishing (secondary processing)

60‧‧‧ curved surface

61‧‧‧ waves

62. PQ, P’Q’, RS, R’S’‧‧‧ segments

71~74‧‧‧The maximum area of surface pressure distribution

92‧‧‧Second processing mold

G‧‧‧Higher height

H, L‧‧‧ meat thick

A, B, C, I‧‧‧ arrow directions

PS‧‧‧Split stroke distance

Wh‧‧‧The gap between the vertical wall portion 55a and the vertical wall portion 55b when rebound is not generated

Wh'‧‧‧ The interval between the vertical wall portion 55a' and the vertical wall portion 55b' at the time of rebound

△Wh‧‧‧Wh’ and Wh difference

W _c ‧‧‧ The gap between the vertical wall portion 55a and the vertical wall portion 55b when no rebound occurs

W _c '‧‧‧ The interval between the vertical wall portion 55a' and the vertical wall portion 55b' at the time of springback generation

Difference between △W _c ‧‧‧W _c ' and W _c

ΔYw‧‧‧The absolute value of the difference between the maximum and minimum values of the graph in the curved surface 60

[ Fig. 1A] Fig. 1A is a view showing a schematic configuration of a press molding die according to a first embodiment of the present invention, and is a perspective view showing the whole.

Fig. 1B is a plan view showing a punching die of a press molding die of the same embodiment.

Fig. 2 is a view showing a press die of a press molding die of the same embodiment, and is a perspective view as seen from the first surface side thereof.

Fig. 3A is an explanatory view schematically showing the operation of a punching die, a rigid die, and a die for pressing a preform, and is a perspective view at the start of press forming.

3B is an explanatory view schematically showing an operation of a punching die, a rigid die, and a die of a press when forming a blank, and is a perspective view in press forming.

[ Fig. 4A] Fig. 4A is a view showing a pressing force increasing portion of the press molding die of the embodiment, and is a longitudinal cross-sectional view showing a state in which the pressing force when the plurality of circular springs are overlapped is not increased.

[Fig. 4B] shows the increase in the pressing force of the press forming mold of the same embodiment. A diagram of the addition portion, and shows a longitudinal section showing a state in which the pressing force of the circular spring is overlapped.

Fig. 5 is a longitudinal cross-sectional view as seen from the direction of the arrow I shown in Fig. 2 .

Fig. 6A is a perspective view showing a press-formed product formed by a press molding die of the same embodiment.

Fig. 6B is a longitudinal cross-sectional view of Fig. 6A as seen from the direction of arrow A.

[ Fig. 7A] Fig. 7A is a view showing a schematic configuration of a press molding die according to a second embodiment of the present invention, and is a perspective view showing the whole.

Fig. 7B is a plan view showing a punching die of a press molding die of the same embodiment.

Fig. 8 is a view showing a press die of a press molding die of the same embodiment, and is a perspective view as seen from the first surface side.

[ Fig. 9A] Fig. 9A is a view showing a schematic configuration of a press molding die according to a third embodiment of the present invention, and is a perspective view showing the whole.

Fig. 9B is a plan view showing a punching die of a press molding die of the same embodiment.

[ Fig. 10A] Fig. 10A is a view showing a schematic configuration of a press molding die according to a fourth embodiment of the present invention, and is a perspective view showing the whole.

Fig. 10B is a plan view showing a punching die of a press molding die of the same embodiment.

Fig. 11 is a view showing a die of a press molding die of the same embodiment, and is a perspective view as seen from the first surface side.

Fig. 12 is a longitudinal cross-sectional view as seen from the direction of arrow C shown in Fig. 11 .

[Fig. 13A] shows a conventional press-formed portion without a pressure receiving portion and a pressing force increasing portion. A schematic view of a mold is shown in the figure, and is a perspective view showing the whole.

Fig. 13B is a plan view showing a punching die of a conventional press forming die having no pressure receiving portion and a pressing force increasing portion.

Fig. 14 is an explanatory view showing a thickness distribution of a flange portion of a press-formed product formed by a conventional press molding die shown in Fig. 13A.

[Fig. 15] Fig. 15 is a view showing a thickness distribution of a flange portion of a press-formed product formed by a conventional press molding die shown in Fig. 13A, and is an illustration of arranging positions of a pressure receiving portion and a pressure increasing portion. Figure.

Fig. 16A is a perspective view showing a press-formed product after finishing (secondary processing).

Fig. 16B is a longitudinal cross-sectional view of Fig. 16A as seen from the direction of arrow B.

FIG. 17 is a view showing a schematic configuration of a secondary processing die for performing finishing (secondary processing), and is a perspective view showing the entire.

Fig. 18 is a longitudinal cross-sectional view perpendicular to the longitudinal direction of the press-formed product after the extrusion bending process, and is an explanatory view showing a state in which the wall is lifted (rebounded).

19 is a longitudinal cross-sectional view in the longitudinal direction of the press-formed product perpendicular to the finishing process (secondary processing), and is an explanatory view showing a state in which the wall is lifted (rebounded).

Fig. 20 is a perspective view showing a press-formed product after finishing (secondary processing), and is an explanatory view showing a state in which waves are generated.

Fig. 21A is a perspective view showing a press-formed product after finishing (secondary processing), and is an explanatory view showing a measurement position of waves.

[Fig. 21B] shows a press-formed product wave after finishing processing (secondary processing) A chart of one example of the wave measurement result.

Fig. 22 is a view showing the surface pressure distribution on the second surface of the press die when the meat thickness ratio L/H of the press die is 100%.

Fig. 23 is a view showing the surface pressure distribution on the second surface of the press mold when the meat mold thickness ratio L/H of the press mold is 90%.

Fig. 24 is a view showing the surface pressure distribution on the second surface of the press mold when the meat mold thickness ratio L/H of the press mold is 80%.

Fig. 25 is a view showing the surface pressure distribution on the second surface of the press mold when the meat mold thickness ratio L/H of the press mold is 70%.

Fig. 26 is a view showing an arrangement position of a pressure receiving portion and a pressing force increasing portion of a press molding die.

Fig. 27 is a view showing an example of a press-molding mold in which the thickness of the press mold is not constant, and is a perspective view showing the whole.

Form for implementing the invention

Hereinafter, each embodiment of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited to the embodiments described below, and various modifications can be made without departing from the scope of the invention. In addition, in order to make the features of the present invention easy to understand, it is convenient to display an important part in an enlarged manner, and the dimensional ratio of each component is not limited to the actual one.

1A and 1B are views showing a schematic configuration of a press molding die according to a first embodiment of the present invention. Fig. 1A is a perspective view of the whole, and Fig. 1B is a plan view of a punching die constituting a press forming mold. In Figure 1A, the symbol 1 is displayed. The press molding die of this embodiment is shown.

The press molding die 1 of the present embodiment includes a punching die 10, a rigid die 20, and die binders 25a and 25b. The punching die 10 has a punching portion 12 and a template portion 14 for transferring the shape of the blank. The punching unit 12 and the formwork unit 14 are fixed by a joint member (not shown) to form a punching die 10. Alternatively, the punching portion 12 may be formed integrally with the die plate portion 12 to form the punching die 10. As shown in Fig. 1B, pressurizing force increasing portions 16a and 16b are disposed on the surface opposite to the die press molds 25a and 25b of the template portion 14, and the pressurizing force increasing portions 16a and 16b are oriented toward the press die 25a, 25b. When protruding and pressed in the pressing direction at the end of press forming, a reaction force in a direction opposite to the direction is generated.

The rigid die 20 is paired with the punching die 10 and disposed opposite to the punching portion 12. The binder molds 25a and 25b are disposed between the punch mold 10 and the rigid mold 20. The press molds 25a and 25b of the present embodiment are configured by the number of the smallest parts which are not easily divided into more than the shape of the press mold and the shape of the press-formed product. That is, the binder molds 25a and 25b can be said to be one type of binder die which is not divided. The press dies 25a and 25b have first faces 31a and 31b that face the stencil portion 14 of the punching die 10 and are in contact with the stencil portion 14 at the end of press forming, and are opposed to the rigid die 20 and The mold 20 holds the second faces 32a, 32b of the blank together.

The side surface (third surface) 33a connected between the first surface 31a and the second surface 32a is opposed to the punching portion 12 by a predetermined gap (pitch). Similarly, the side surface (third surface) 33b connected between the first surface 31b and the second surface 32b is opposed to the punching portion 12 by a predetermined gap (pitch). By appropriately setting these gaps, it is possible to suitably prevent the occurrence of the bending of the press-formed product or the breakage of the press-formed product. crack. The setting of these gaps can be determined as long as it follows the convention.

Fig. 2 is a perspective view of the binder molds 25a, 25b as viewed from the side of the first faces 31a, 31b. As shown in Fig. 2, the press dies 25a, 25b individually have pressure receiving portions for receiving the reaction forces of the first faces 31a, 31b for elastically deforming the die dies 25a, 25b at the end of press forming ( Grooves 30a, 30b. In the press molding die 1 of the present embodiment, the pressure receiving portions 30a and 30b are formed by groove portions. At the end of the press forming, when the pressurizing force increasing portions 16a, 16b are individually brought into contact with the pressure receiving portions 30a, 30b and pressed in the pressing direction, and a reaction force is generated in the opposite direction, the press molds 25a, 25b are accepted. This reaction force is elastically deformed.

3A and FIG. 3B are explanatory views schematically showing the operation of the punching mold 10, the rigid mold 20, and the press molds 25a and 25b when the blanks 5 are press-formed. Fig. 3A is a perspective view showing the start of press forming, and Fig. 3B is a perspective view showing press forming.

The blanks 5 are placed on the second faces 32a, 32b of the press dies 25a, 25b at the same height as the front end faces 13 of the punching portion 12.

As shown in Fig. 3A, the rigid die 20 is lowered in the pressing direction, and the flange portion of the blank 5 is held by the rigid die 20 and the die 25a, 25b with a certain load.

Further, as shown in Fig. 3B, in a state where the blank 5 is held by the die 20 and the die 25a, 25b, the rigid die 20 is oriented in the pressing direction, that is, the direction of the template portion 14 of the punching die 10 (in the Moving downward in Fig. 3B), press forming of the blank 5 of the punching portion 12 can be performed.

At a predetermined position at the end of press forming, placed in a die The pressure receiving portions 30a and 30b of the first faces 31a and 31b of the 25a and 25b are in contact with the pressing force increasing portions 16a and 16b. In addition, the pressure receiving portions 30a and 30b press the pressing force increasing portions 16a and 16b in the pressing direction in conjunction with the press forming from the predetermined position at the end of the press forming to the end of the press forming. As a result, the reaction force from the pressing force increasing portions 16a and 16b in the opposite direction to the pressing direction is generated, and the pressure receiving portions 30a and 30b receive the reaction force, and the pressing force for the blank 5 at the end of the press forming is increased. .

4A and 4B are longitudinal cross-sectional views showing a state in which a plurality of circular springs as a pressing force increasing portion are overlapped. Fig. 4A shows a state in which the pressing force is not increased, and Fig. 4B shows a state in which the pressing force is increased.

As shown in FIG. 4A, the pressing force increasing portion 16a has a plug 40a and a circular spring 42a. As described above, the pressing force increasing portion 16a has an elastic body that imparts the above reaction force. In the present embodiment, the twelve circular springs 42a are arranged in parallel in parallel and overlap each other. However, the number and arrangement of the circular springs 42a are not limited to this. For example, four circular springs 42a may be stacked in series. However, although not shown, the pressing force increasing portion 16b is also the same as described above.

Further, instead of the circular spring 42a, an elastic body such as a coil spring or rubber may be used. However, by obtaining a high load-bearing point with a low stroke, it is preferable to use the circular spring 42a.

As shown in Fig. 4B, the pressure receiving portion 30a provided on the first surface 31a of the die metal mold 25a is pressed by pressing the plug 40a in the pressing direction, and the circular spring 42a is contracted. Further, the press mold 25a receives a reaction force from the circular spring 42a in the opposite direction to the pressing direction. As a result, the reaction force can be transmitted to the blank 5 held between the second surface 32a of the die mold 25a and the rigid die 20, and the blank can be made to the blank. The pressing force of 5 is increased at the end of press forming.

Since the press mold 25a that receives the reaction force from the circular spring 42a has the pressure receiving portion 30a having the groove portion, it is elastically deformed on the side of the blank 5 and is bent into a convex shape. That is, the elastic deformation of the convex portion of the second surface 32a causes the reaction force to be efficiently transmitted to the blank 5, and the convex portion of the second surface 32a is observed along the pressing direction, and the pressing die 25a. The pressure receiving portion 30a formed by the first surface 31a corresponds to each other. When the press mold 25a has no pressure receiving portion 30a, the reaction force from the circular spring 42a is diffused to the entire press mold 25a. Therefore, since the reaction force cannot be locally applied to the blank 5, the efficiency of transmitting the reaction force is rather low.

Fig. 5 is a view showing the thickness of the die of the die 25a, and a longitudinal section of the die 25a as seen from the direction of the arrow I shown in Fig. 2. As shown in Fig. 5, a die of a press die 25a having a pressure portion 30a formed in a groove portion is regarded as L in a unit thickness of mm, and a press die in a region where the pressure receiving portion 30a is removed and the blank 5 is joined. 25a flesh thickness is treated as H in units of mm. Further, in the press molding die 1 of the present embodiment, the meat thickness H is constant. However, when the thickness of the meat is not constant, the minimum thickness of the meat in the region where the pressure receiving portion 30a is removed and which is in contact with the blank 5 is regarded as H. The case where the thickness H of the meat is not constant is, for example, a case where the press-formed product having a flange surface height is not fixed is formed as shown in Fig. 27 .

The lower limit of the thickness L of the meat should be 20 mm. When the thickness L of the meat is less than 20 mm, the press mold 25a may be plastically deformed or broken during the extrusion bending process (during press forming). On the other hand, when 40 ≦H ≦ 50, the upper limit of the meat thickness L is preferably 0.8 x H. When the meat thickness L exceeds 0.8 × H, even if the pressure receiving portion 30a receives the reaction force from the pressing force increasing portion 16a, the pressing die 25a does not It will be elastically deformed, and there will be a situation in which the reaction force cannot be efficiently transmitted to the blank 5. On the other hand, the upper limit of the appropriate meat thickness L at 40 ≦H ≦ 50 is 0.6×H. When the upper limit of the meat thickness L is 0.6 × H, even if the capacity of the pressing force increasing portion 16a is small, the reaction force from the pressing force increasing portion 16a can be efficiently transmitted to the blank 5.

Further, when 50 < H ≦ 80, regardless of the thickness H, the upper limit of the thickness L of the meat is preferably 40 mm. The maximum reaction force received by the pressure receiving portion 30a from the pressing force increasing portion 16a is 6.5 MPa. Therefore, when the thickness L of the meat exceeds 40 mm, the rigidity of the pressed portion 30a becomes high, and even if the maximum value of the reaction force is reached, the press mold 25 is not elastically deformed.

Further, when the meat thickness H is less than 40 mm, the rigidity of the entire press mold 25a is insufficient. On the other hand, when the meat thickness H exceeds 80 mm, the rigidity of the press mold 25a becomes larger than necessary, and the material cost of the press mold 25a is also wasted.

When finishing the meat thickness of the press mold 25a, the relationship between the meat thickness L and the meat thickness H should preferably satisfy the relationship of the following formula 1 or formula 2. However, although not shown, the die 25b is also the same as described above.

40≦H≦50, 20≦L≦0.8×H. . . (Formula 1)

50<H≦80, 20≦L≦40. . . (Formula 2)

The reaction force from the pressing force increasing portion 16a is generated from the contact between the pressure receiving portion 30a provided in the die metal mold 25a and the pin 40a until the end of the press forming. Further, the position where the pressure receiving portion 30a of the press mold 25a is in contact with the plug 40a may be a predetermined position at the end of press forming. Moreover, the position of the pressure receiving portion 30a in contact with the pin 40a can be changed by changing the pin 40a. The length is controlled by the length (height) of the protrusion from the surface of the template 14.

The height G at which the front end of the plug 40a shown in Fig. 4A protrudes from the surface of the stencil 14 may be a distance from the surface of the stencil portion 14 to the predetermined position at which the pressing force is to be increased at the end of press forming, and the pressure receiving portion 30a is formed by the groove portion. The height of the groove (the value of L subtracted from H) plus the height.

Specifically, the height at which the leading end of the pin 40a of the pressing force increasing portion 16a protrudes from the surface of the template 14 is regarded as G in units of mm, and the pressing stroke position from the plastic deformation of the blank 5, that is, the pressing forming start point to the pressing When the pressing stroke distance from the end point of molding is regarded as PS in units of mm, the protruding height G of the pressing force increasing portion 16a preferably satisfies the following Expression 3. However, although not shown, the pressing force increasing portion 16b is also the same as described above.

0.02×PS+H-L≦G≦0.3×PS+H-L. . . (Formula 3)

It is preferable that the protruding height G of the plug 40a is equal to or greater than 2% (0.02 × PS) of the pressing stroke distance PS plus the groove depth (H-L) of the pressure receiving portion 30a. That is, the interval of the pressing stroke in which the pressing force is increased at the end of press forming is preferably 2% or more of the pressing stroke distance PS. When the protruding height G is smaller than the above value (0.02 × PS + H - L), the increase in the pressing force may be insufficient, and the effect of reducing the rebound may become unstable. Further, in order to reduce the rebound more, it is preferable to set the value of the protruding height G to be (0.05 × PS + H - L) or more.

On the other hand, it is preferable that the protruding height G of the plug 40a is equal to or less than 30% (0.3 × PS) of the pressing stroke distance PS plus the groove depth (H-L) of the pressure receiving portion 30a. That is, the section of the pressing stroke in which the pressing force is increased at the end of press forming is preferably 30% or less of the pressing stroke distance PS. Since the protruding height G exceeds the above value (0.3×PS+H-L), the range in which the pressing force is increased is increased. It will be too long, so the difference in the strength of the pressing force will be small from the start of the press forming to the end of the press forming. Therefore, only the effect of increasing the pressing force at the end of the press forming is weak, and there is a case where the rebound is more conspicuous. Further, in order to further reduce the rebound, it is preferable that the value of the protruding height G is equal to or less than (0.15 × PS + H - L).

The pressing die 25a and the pressing force increasing portion 16a have been mainly described so far, and the pressing die 25b and the pressing force increasing portion 16b are also the same.

Fig. 6A and Fig. 6B show a press-formed product formed by the press molding die 1 of the present embodiment. Fig. 6A is a perspective view, and Fig. 6B is a longitudinal sectional view of Fig. 6A as seen from the direction of arrow A. In Fig. 6A and Fig. 6B, reference numeral 50 shows a press-formed product.

The press-formed product 50 has flange portions 54a and 54b, vertical wall portions 55a and 55b, and a top portion 55c. Further, at both ends of the press-formed product 50, straight portions 51a and 51b and curved portions 52 which are sandwiched by the straight portions 51a and 51b are provided. When the cross-section perpendicular to the longitudinal direction is observed, the press-formed product 50 has a so-called cross-sectional hat shape, and both ends of the press-formed product 50 in the longitudinal direction are openings. Here, the cross-sectional hat shape refers to a shape of the top portion 55c provided at the center portion in the width direction and one end portion from the top portion 55c toward the top portion 55c when viewed in the direction of the arrow A. The vertical wall portions 55a and 55b which are provided obliquely on the front side, and the flange portions 54a and 54b which are provided in parallel with the front end of the vertical wall portions 55a and 55b to the top portion 55c.

At the time of press forming, depending on the shape of the press-formed product 50, a portion which is easily caused by the plastic flow of the blank 5 and a portion which is hard to be caused may be generated. According to the difference in the ease of the plastic flow, the sheet of the molded article 50 is pressed. The residual stress in the thick direction or the in-plane direction may be uneven. Further, due to the unevenness of the residual stress, springback of the press-formed product 50 such as the vertical wall portions 55a and 55b, the twist, the wave, and the like occur. In particular, when the shape of the press-formed product 50 has a bent portion, the shrinkage flange deformation or the extension flange deformation occurs in the longitudinal direction of the press-formed product 50. Therefore, the unevenness of the residual stress in the thickness direction or the in-plane direction increases.

In general, the press-formed product 50 is subjected to finishing processing (secondary processing) after the extrusion bending process. When the press-formed product 50 is processed into a shape of the press-formed product 57 as shown in FIG. 16A and FIG. 16B described later by secondary processing, significant waves are generated in the vertical wall portion 55a of the curved portion 52 and the like. In order to reduce the dimensional accuracy of the reduced-pressure molded product 57, generally, the amount of deformation of the rebound is first predicted according to the mold size at the time of mold design, but when the rebound is a wave, it is quite difficult to predict the amount of deformation. Further, in order to solve the correction of the mold which is performed by pressing the wave of the molded product 57, the correction of the mold requires a considerable amount of time and expense due to an attempted error.

This wave system is formed by extrusion bending (press molding), and the vertical wall portion 55a of the curved portion 52 becomes a stretched flange deformation region. Therefore, the tensile stress in the longitudinal direction of the press-formed product 50 is increased, and the residual stress in the thickness direction or the in-plane direction of the press-formed product 50 contributes to unevenness. Due to the unevenness of these residual stresses of the press-formed product 50 after the extrusion bending, the press-formed product 57 after the secondary processing is generated by waves. Therefore, in order to eliminate the wave of the curved portion 52, it is preferable to increase the pressing force at the curved portion 52 at the end of the press forming of the extrusion bending process.

As shown in FIG. 1A to FIG. 2, compared with the straight side portions 51a and 51b, The pressing force at the bending portion 52 at the end of the press forming is increased, and the pressure receiving portions 25a and 30b are individually provided with the pressure receiving portions 30a and 30b. Further, in order to elastically deform the binder molds 25a and 25b at the end of the press forming, the pressurizing force increasing portions 16a and 16b are disposed in the formwork portion 14.

As described above, the pressing force is increased at the end of the press forming, whereby the tension generated by the extending flange deformation, that is, the tension of the vertical wall portion 55a of the curved portion 52 is increased. As a result, the unevenness of the residual stress in the thickness direction or the in-plane direction of the press-formed product 50 due to the rebound is reduced. However, the area where the contraction flange is deformed is also the same as described above. That is, as described above, the pressing force is increased at the end of the press forming, whereby the tension generated by the contraction flange, that is, the tension of the vertical wall portion 55b of the curved portion 52 is also increased. As a result, the rebound in the region where the contraction flange is deformed is also reduced.

When the pressure receiving portions 25a, 30b are not provided with the pressure receiving portions 25a, 30b, the binder molds 25a, 25b are not elastically deformed. Further, the reaction forces from the pressurizing force increasing portions 16a and 16b are dispersed to the entire press molds 25a and 25b. Therefore, at the end of the press forming, the pressing force cannot be locally increased in the curved portion 52, and the pressing force required for the bending portion 52 cannot be given. As a result, it is impossible to apply only the tension required for suppressing the rebound to the vertical wall portions 55a and 55b of the curved portion 52. Therefore, the effect of reducing the rebound of the molded article 50 is remarkably lowered.

Further, in order to reduce the dispersion of the reaction forces from the above-described pressing force increasing portions 16a and 16b by increasing the ability of the pressing force increasing portions 16a and 16b, for example, it is necessary to increase the straightness of the circular spring 42a, or Yes, increase the number of the circular springs 42a. At this time, the pressing force increasing portions 16a and 16b themselves become large.

On the other hand, if you want high tensile steel or high strength aluminum alloy, etc. In the case of press forming of a sheet metal having a large plastic flow resistance and a large rebound, it is necessary to bend the shape of the press-formed product 50 and to deform the flange or deform the flange to generate a pressing force at the end of the press forming. Especially bigger. Therefore, when press forming a high-tensile steel or a high-strength aluminum alloy or the like, and if the dispersion of the reaction force is to be reduced by increasing the capacity of the pressurizing force increasing portions 16a and 16b, it is necessary to increase the pressing force increasing portion 16a. 16b becomes very large. Therefore, it is quite difficult to arrange the pressing force increasing portions 16a and 16b in the press molding die 1.

Next, a press molding die according to a second embodiment of the present invention will be described. 7A and 7B are views showing a schematic configuration of a press molding die according to a second embodiment of the present invention. Fig. 7A is an overall perspective view, and Fig. 7B is a plan view of a punching mold constituting a press forming mold. Fig. 8 is a perspective view of the press mold of the press molding die of the embodiment as viewed from the first surface side.

In the press molding die 2 of the present embodiment, except that the pressurizing force increasing portion 16b is disposed only in the die plate portion 14, the pressure receiving portion 30b including the groove portion is disposed only in the press die 25b, and the press die 25e is not provided with the pressure receiving portion. Both of them are the same as the press molding die 1 of the first embodiment described above.

The press-molding mold 2 of the present embodiment can increase the pressing force to the blank 5 only in the region where the extended flange is deformed, in other words, only in the portion where the pressing force is particularly required. In other words, when the tensile strength of the blank 5 is not as high, or the curvature of the curved portion 52 of the press-formed product 50 or the like, the pressure receiving portion 30b and the pressing force increasing portion 16b can be individually disposed.

Next, a press molding die according to a third embodiment of the present invention will be described. 9A and 9B show the press molding of the third embodiment of the present invention. A schematic diagram of a shape of a mold. Fig. 9A is an overall perspective view, and Fig. 9B is a plan view of a punching mold constituting a press forming mold.

The press molding die 3 of the present embodiment is the same as the press molding die 1 of the above-described first embodiment except that the pressurizing force increasing portions 16a, 16b, 16c, 16d, 16e, and 16f are disposed in the form portion 14. Further, the press dies 25a and 25b of the press molding die 3 of the present embodiment shown in Fig. 9A are the same as the die dies 25a and 25b of the press molding die 1 of the first embodiment shown in Fig. 2 .

As shown in Fig. 9A and Fig. 9B, the press-molding mold 3 of the present embodiment has an increase in the pressing force in addition to the pressing force increasing portions 16a and 16b which are in contact with the pressure receiving portions 30a and 30b at the end of press forming. Part 16c~16f. Therefore, the pressing force to the blank 5 can be precisely controlled at the end of the press forming. However, the pressing force increasing portions 16c to 16f which are in contact with the first faces 31a and 31b of the non-pressure receiving portions 30a and 30b are compared with the pressing force increasing portions 16a and 16b which are in contact with the pressure receiving portions 30a and 30b, and then the hair is raised. The effect of increasing the pressing force of the embryo 5 is small. In other words, whether or not the pressing force increasing portions 16c to 16f that are in contact with the first faces 31a and 31b of the non-pressure receiving portions 30a and 30b are to be disposed can be determined according to the shape of the press-molded article or the structure of the press die.

Next, a press molding die according to a fourth embodiment of the present invention will be described. 10A and FIG. 10B are views showing a schematic configuration of a press molding die according to a fourth embodiment of the present invention. Fig. 10A is an overall perspective view, and Fig. 10B is a plan view of a punching mold constituting a press forming mold. Fig. 11 is a perspective view of the press mold of the press molding die of the embodiment as viewed from the first surface side. Figure 12 is a view for explaining a die of the present embodiment, and is a view of the same. A longitudinal section of the die is observed in the direction of arrow C shown in FIG.

The press molding die 4 of the present embodiment includes the groove portions 35c and 35d, and the groove portions 35c and 35d are a part of the boundary and divide the pressure receiving portions 30c and 30d, except that the pressure receiving portions 30c and 30d of the die tools 25c and 25d include the groove portions 35c and 35d. It is the same as the press molding die 1 of the above-described first embodiment. Further, the punching die 10 of the present embodiment shown in Fig. 10B is the same as the punching die 10 of the first embodiment.

From the viewpoint of the structure of the press mold and the shape of the press-formed product, the press dies 25c and 25d of the present embodiment are configured by the minimum number of parts which are not easily divided into more than the above. That is, the binder molds 25c and 25d can be said to be a non-divided type and are an integral type of die. The press dies 25c and 25d have first faces 31c and 31d that face the stencil portion 14 of the punching die 10 and are in contact with the stencil portion 14 at the end of press forming, and are opposed to the rigid die 20 and The mold 20 holds the second faces 32c, 32d of the blank 5 together.

The binder molds 25c and 25d individually have pressure receiving portions 30c and 30d that receive the reaction forces for elastically deforming the binder molds 25c and 25d at the end of press forming on the first surfaces 31c and 31d. The pressure receiving portions 30c and 30d include groove portions 35c and 35d. The groove portions 35c and 35d are a part of the boundary, and the pressure receiving portions 30c and 30d are defined on the first surfaces 31c and 31d. Specifically, as shown in FIG. 11, the pressure receiving portions 30c and 30d are defined by the groove portions 35c and 35d and a part of the edges of the first faces 31c and 31d on the first faces 31c and 31d.

At the end of the press forming, the pressure receiving portions 30c, 30d are in contact with the pressing force increasing portions 16a, 16b, and the press dies 25c, 25d are elastically deformed. As a result, it is possible to locally add a pressing material to a portion where the pressing force of the blank 5 is to be increased. force. Therefore, since the pressing force of the contraction flange deformation region or the extension flange deformation region can be locally increased at the end of the press forming, the rebound can be effectively suppressed.

At the end of the press forming, when the press dies 25c and 25d receive the reaction forces from the pressurizing force increasing portions 16a and 16b by the pressure receiving portions 30c and 30d, since the dies 25c and 25d have the grooves 35c and 35d, the above reaction occurs. The force is not dispersed to the entire press molds 25c, 25d. When the reaction force is received from the pressurizing force increasing portions 16a and 16b, the press dies 25c and 25d have the groove portions 35c and 35d as the boundary, and are elastically deformed into a convex shape on the rigid die 20 (the blank 5) side. As a result, the blank force 5 can locally and collectively increase the pressing force.

Further, the depth, the width, and the like of the groove portions 35c and 35d of the present embodiment are not particularly limited. The groove portions 35c and 35d may be of a suitable size as long as they can correspond to the shape of the press-formed product 50 or the structure of the press mold 4. Further, the die halves 25c and 25d of the pressure receiving portions 30c and 30d of the groove portions 35c and 35d are removed from the die L, and the press die 25c in the region where the pressure receiving portions 30c and 30d are removed and in contact with the blank 5 are removed. 25d meat thickness H is also not particularly limited. In the present embodiment, the meat thickness L and the meat thickness H are the same thickness, but the meat thickness L may be 20 ≦L ≦H. In addition, when the meat thickness L satisfies 20 ≦L ≦ H, the protruding height G of the pressing force increasing portions 16a and 16b is 0.02 × PS + HL ≦ G ≦ 0.3 × PS + HL as in the first embodiment. can.

The press molding dies 1 to 4 according to the first embodiment to the fourth embodiment of the present invention have been described above. Next, the position where the effective positions of the pressure receiving portions 16a to 16f and the pressure receiving portions 30a to 30d are located is explained.

13A and 13B are views showing a schematic configuration of a conventional press molding die having no pressure receiving portion and a pressing force increasing portion. Fig. 13A is an overall perspective view, and Fig. 13B is a plan view showing a punching mold constituting a conventional press forming mold. In Fig. 13A, reference numeral 91 shows a conventional press forming mold.

Fig. 14 is an explanatory view showing the thickness distribution of the flange portion of the press-formed product when the blank press 5 having a thickness of 1.0 mm has been subjected to extrusion bending (press forming) using the conventional press forming mold shown in Fig. 13A. . That is, FIG. 14 is a view showing a state in which the preform 5 is pressed by the press forming mold 91 shown in FIG. 13A and subjected to press bending (press forming), and the rigid mold 20 is omitted and pressed. The plan to look at the direction. In Fig. 14, the measurement results of the thickness of the flange portions 54a and 54b are collectively described. As shown in Fig. 14, the flange portions 54a and 54b have a curved outer side portion 6a, a curved inner side portion 6b, and straight portions 6c, 6d, 6e, and 6f.

As shown in Fig. 14, the curved outer side portion 6a is relatively thick in thickness. The curved outer side portion 6a is the largest portion having the largest thickness in the flange portions 54a and 54b of the press-formed product 50. On the other hand, the curved inner portion 6b has a thin plate thickness. As described above, in the press-formed product 50 which is press-formed by using the conventional press molding die 91, the thickness of each portion in the flange portions 54a and 54b is not the same. The second faces 32e, 32f of the press dies 25e, 25f held by the blank 5 and the rigid die 20 are flat. Therefore, in the press molding die 91 in which the pressure receiving portions 30a to 30d of the press dies 25e and 25f are not provided, during the press forming, when the thickness of each portion in the flange portions 54a and 54b is changed, there is a strong pressing force. The site of action and the site of weak action exist. When the magnitude of the pressing force changes depending on the location during press forming, the plastic flow balance of the blank 5 during plastic deformation collapses. As a result, the dimensional accuracy of the press-formed product 50 after press forming is lowered.

In order to suppress the decrease in the dimensional accuracy of the press-formed product 50 due to the coexistence of the above-mentioned pressing force and the weakly acting portion, it is preferable to reduce the thickness of the plate in the flange portions 54a and 54b during press forming. The pressing force is increased at the end of the press forming. Specifically, the flange portion 54a of the press-formed product 50 is preferably based on the conventional press-molding mold 91 from which the pressure-receiving portions 30a to 30d and the press-force increasing portions 16a to 16f have been removed from the press-molding molds 1 to 4. In the case of 54b, the maximum thickness of the plate is regarded as the maximum thickness of the plate, and the area where the maximum thickness of the plate thickness exceeds 0% and 97% or less is regarded as the thickness reduction portion, and is observed along the pressing direction. In the case of the pressure receiving portions 30a to 30d of the binders 25a to 25d, one of the thickness reduction portions of the blank 5 is partially overlapped. As a result, the pressing force at the portion where the thickness is reduced in the flange portions 54a and 54b during press forming can be suitably increased at the end of the press forming. By the pressing force of the thickness reduction portion of the maximum thickness of the sheet thickness of more than 0% and 97% or less, the pressing force at the end of the press forming is appropriately increased, and the rebound of the press-formed product 50 can be effectively performed. The land is reduced.

Fig. 15 is a view showing the thickness distribution of the flange portion of the press-formed product formed by the conventional press-molding mold shown in Fig. 13A, and is an explanatory view exemplifying a suitable position of the pressure receiving portion and the pressurizing force increasing portion. . In other words, Fig. 15 is an explanatory view showing an example in which the positions of the pressure receiving portions 30b and 30d and the pressing force increasing portion 16b are overlapped with Fig. 14 .

As shown in Fig. 15, in the flange portions 54a and 54b of the press-formed product 50 which has been press-molded by the conventional press molding die 91, it is preferable to arrange the pressure receiving portions 30b and 30d to bend the plate thickness reducing portion. Part of the inner side portion 6b is heavy The plate thickness reduction portion is more than 0% and 97% or less with respect to the curved outer side portion 6a which is the largest thickness portion. Moreover, when the pressurizing force increasing portion 16b is disposed so as to protrude toward the pressure receiving portions 30b and 30d and press in the pressing direction, the reaction force in the opposite direction is generated and the binder molds 25b and 25d are elastically deformed. As a result, in the press forming, in the flange portions 54a and 54b, the pressing force of the curved inner side portion 6b whose thickness is reduced can be suitably increased at the end of the press forming.

As described above, by arranging the pressure receiving portions 30b and 30d and the pressing force increasing portion 16b, the press dies 25b and 25d can be elastically deformed on the side of the blank 5 of the pressure receiving portions 30b and 30d at the end of the press forming. The shape and the pressing force can be locally and concentratedly increased in the curved inner portion 6b.

The press-molding mold of each aspect of the present invention described above is organized as follows.

(1) The press molding dies 1 to 4 of the respective embodiments of the present invention include a punching die 10 having a punching portion 12 and a stencil portion 14 for transferring a shape to the blank 5; a rigid die 20, and a punching die 10 pairs and opposite to the punching portion 12; the first faces 31a to 31d are opposite to the template portion 14 and are in contact with the template portion 14 at the end of press forming; the second faces 32a to 32d are connected to the die 20 Opposing and holding the blank 5 together with the rigid mold 20; and the side surfaces (third surface) 33a, 33b are connected between the first surfaces 31a to 31d and the second surfaces 32a to 32d and opposed to the punch portion 12 And a press die 25a-25d which is arranged to pass through the gap between the side (third face) 33a, 33b and the punching portion 12, and a pressure receiving portion 30a to 30d for receiving the die 25a~ The first surface 31a to 31d of the 25d is used for the groove portion of the reaction force of the elastic deformation of the press molds 25a to 25d at the end of press forming; The material-enhancing portions 16a and 16b are formed so as to face the pressure-receiving portions 30a to 30d on the surface opposite to the first surfaces 31a to 31d of the template portion 14, and are pressed in the pressing direction at the end of the press forming. The reaction of the direction is generated.

(2) In the case where the pressure receiving portions 30a to 30d and the pressing force increasing portions 16a and 16b are removed from the press molding dies 1 to 4, the flange portions 54a and 54b of the press-formed product 50 are made thick. When the maximum thickness is the maximum thickness, the area where the thickness exceeds 0% and 97% or less is used as the thickness reduction portion, and when the thickness is reduced, the pressure is measured in the pressing direction. 30a to 30d may overlap with a part of a region corresponding to the thickness reduction portion of the blank 5 .

(3) The pressure receiving portions 30a and 30b may be formed by the groove portion, and the thickness of the pressing dies 25a and 25b at the positions of the pressure receiving portions (groove portions) 30a and 30b is L in units of mm, and the pressure receiving portion is removed. When the minimum thickness of the die 25a, 25b of the groove portion 30a, 30b and the position where the blank 5 is in contact with the blank 5 is regarded as H in units of mm, the die 25a, 25b may satisfy the following formula 1 or formula 2, and The protruding height of the surface of the template portion 14 of the pressing force applying portions 16a, 16b is regarded as G in units of mm, and the pressing stroke distance from the press forming start point to the press forming end point is regarded as PS in units of mm, and the pressing material is pressed. The aforementioned protruding height G of the force applying portions 16a and 16b can satisfy the following Expression 3.

40≦H≦50, 20≦L≦0.8×H. . . (Formula 1)

50<H≦80, 20≦L≦40. . . (Formula 2)

0.02×PS+H-L≦G≦0.3×PS+H-L. . . (Formula 3)

(4) Further, a part of the boundary between the pressure receiving portions 30c and 30d may be the groove portions 35c and 35d. Specifically, the pressure receiving portions 30c and 30d include a groove portion 35c and 35d, the groove portions 35c and 35d can be one of the boundaries, and the pressure receiving portions 30c and 30d are divided on the first surfaces 31c and 31d.

(5) Further, the pressing force increasing portions 16a, 16b may have an elastic body that imparts a reaction force.

(6) Further, the elastic body may be at least one of a circular spring 42a, a coil spring, and a rubber.

Next, a method of manufacturing the press-formed product 50 which is press-formed using the press-molding molds 1 to 4 of the above-described embodiment of the present invention will be described.

The method for producing a press-molded article 50 according to one aspect of the present invention includes the steps of using the press-molding molds 1 to 4 of the above-described form, and taking the forming start position of the press stroke when the blank is formed into a blank as 5%. When the forming end position of the pressing stroke is 0%, the pressing force for a part of the blank 5 in the press forming is completed at the end of the press forming from the position where the pressing stroke is 2% or more and 30% or less to the forming end position. increase.

According to the method for producing the press-formed product 50 described above, it is possible to suppress the rebound and obtain the press-formed product 50 having a high dimensional accuracy. In the above manufacturing method, when the pressing stroke position at which the pressing force starts to increase is less than 2%, the increase in the pressing force is insufficient, and the effect of reducing the rebound becomes unstable. On the other hand, when the pressing stroke position at which the pressing force starts to increase exceeds 30%, since the interval in which the pressing force is increased is too long, between the forming start position of the pressing stroke and the end position of the pressing stroke forming, the pressing is performed. The difference in strength and strength will become smaller. Therefore, the effect of increasing the pressing force only at the end of the press forming is weak, and there is a case where the rebound is more conspicuous. Moreover, in order to reduce the rebound more, the pressing stroke position at which the pressing force starts to increase is 5% or more and 15% or less.

[Example 1]

The effects of the above aspects of the present invention will be further described by way of examples. However, the conditions of the examples are employed in order to confirm the implementation possibilities and effects of the present invention, and the present invention is not limited to the one condition. The present invention can be applied to various conditions as long as the object of the present invention can be achieved without departing from the gist of the present invention.

(Example 1)

The high tensile steel sheet is laser cut into a predetermined shape to obtain a blank 5 . The blank 5 is subjected to extrusion bending (press molding) to have a shape of a cross-hat shape. Further, after the extrusion bending process, finishing processing (secondary processing) is performed. The conditions and the like of each of the above-described items are described below.

A high-tensile steel sheet having a thickness of 1.0 mm and a tensile strength of 590 MPa was used as a material, and laser cutting was performed to obtain a blank 5, and the shape after finishing (secondary processing) was changed as shown in FIGS. 16A and 16B. The cross-sectional width is shown as: 60 mm and height: 80 mm.

The press molding die 1 shown in Figs. 1A to 2 (the press molding die 1 of the first embodiment described above) and the press molding die 2 shown in Figs. 7A to 8 (the press molding die 2 of the second embodiment described above) are used. And the press molding die 3 shown in FIG. 9A and FIG. 9B (the press-molding die 3 of the above-described third embodiment), the blank 5 is subjected to extrusion bending (press molding) to be changed into FIGS. 6A and 6B. The shape shown (section hat shape).

As the pressing force increasing portions 16a to 16f, a circular spring unit in which the circular spring 42a shown in Fig. 4A is combined is used. Pressing force increasing portions 16a to 16f are under pressure The load (reaction force) given to the press dies 25a and 25b at the end of the molding is changed according to the number of the circular springs 42a and the combination method (parallel, series, parallel series). In addition, the press molding die 3 (the press molding die 3 of the third embodiment) shown in FIG. 9A and FIG. 9B is provided with the pressurizing force increasing portions 16c to 16f in addition to the pressure receiving portions 30a and 30b.

The thickness H of the press dies 25a and 25b in the region where the pressure receiving portions 30a and 30b are removed and in contact with the blank 5, and the thickness L of the dies 25a and 25b of the pressure receiving portions 30a and 30b are The meat thickness ratio L/H is shown in Table 1.

Moreover, in Table 1, it is noted that the pressurizing force increasing portions 16a to 16f for the press dies 25a and 25b are loaded (reaction force). This load is displayed by the total value of the load weight of the circular spring unit disposed in the press molding dies 1 to 3.

For example, in the inventive example No. 6, the press forming mold 3 shown in Figs. 9A and 9B was used. At this time, six pressurizing force increasing portions 16a to 16f are disposed. The load (reaction force) applied to the press dies 25a and 25b by one of the press force increasing portions 16a to 16f is 100 kN. Therefore, the total of these load (reaction forces) is 600 kN (100 kN × 6).

Moreover, in the conventional example No. 14, the press-molding mold 91 which has no pressure-receiving parts 30a and 30b and the press-force-force-increasing parts 16a-16f shown in FIG. 13A and FIG. Moreover, in Reference Example 1, the press molding die 1 having the same thickness H and the thickness L of the press dies 25a and 25b was used. In other words, the press-molding mold 1 used in Reference Example 1 is a press-molding mold in which a press mold 25e, 25f having no pressure-receiving portion and a punch mold 10 having press-force increasing portions 16a and 16b are combined.

Extrusion bending (compression molding) was carried out using a press forming apparatus having a capacity of 1960 kN (200 tons). Further, a load weight (a total value of the load applied to the press dies 25a and 25b) was applied: 196 kN (20 tons), and press forming was performed as shown in Fig. 6B until the height of the press-formed product 50 became 60 mm. The same applies to the conventional example No. 14. On the other hand, the press forming apparatus which has been used does not have a variable mold pad apparatus or the like, and is a general press forming apparatus.

In the examples of the present invention and the reference examples No. 1 to No. 10, the increase in the pressing force at the end of the press forming was started from the height of 9 mm in front of the end of the press forming. In other words, the protruding height G of the pressing force increasing portions 16a and 16b that are in contact with the pressure receiving portions 30a and 30b at the end of the press forming is set to be 9 mm to the depth (HL) of the pressure receiving portions 30a and 30b. The value. The pressing stroke distance PS from the press forming start point to the press forming end point was 60 mm. That is, the press stroke forming start position at the time of press forming the blank 5 is regarded as 100%, and when the press stroke forming end position is regarded as 0%, the pressing stroke position at which the pressing force starts to increase is 15%. Here, the pressing force increasing portions 16a and 16b which are in contact with the pressure receiving portions 30a and 30b at the end of the press forming will be described, but the pressing members which are not in contact with the pressure receiving portions 30a and 30b at the end of the press forming are used. In the force increasing portions 16c to 16f, the protruding height G is set to 9 mm.

Further, in the examples of the present invention and No. 11 to No. 13 of the reference example, the increase in the pressing force at the end of the press forming was controlled as follows. That is, as shown in Table 1, the depth (H-L) of the pressure receiving portions 30a and 30b is made constant, and by changing the value of the protruding height G, the position at which the pressing force starts to increase is controlled. In the present invention example No. 11, from the height of 20 mm in front of the end of the press forming (pressing punch) The process is in the position of 33%), and the height of the present invention No. 12 from the end of the press forming end point of 1.5 mm (the position where the press stroke is 2.5%), and from the end of the press forming end point of the present invention No. 13 1.1. The height of mm (the position where the pressing stroke is 1.8%) causes the pressing force to start to increase.

The press-formed product 50 obtained by the above-described extrusion bending process (press molding) is subjected to finishing processing (secondary processing).

16A and 16B are views showing a press-formed product after finishing (secondary processing). Fig. 16A is a perspective view, and Fig. 16B is a longitudinal sectional view of Fig. 16A as seen from the direction of arrow B. In Fig. 16A and Fig. 16B, reference numeral 57 is a press-formed product after finishing (secondary processing).

Fig. 17 is a view showing a schematic configuration of a secondary processing die for performing finishing (secondary processing), and is a perspective view showing the entire. In Fig. 17, reference numeral 92 denotes a secondary processing die.

The press-formed product 50 obtained by extrusion bending (press molding) inserts the cap portion surrounded by the vertical wall portions 55a, 55b and the top portion 55c toward the punch portion 12 of the secondary processing die 92, and can be pressed by the pad portion 18. Top 55c. Further, the punching portion 12 and the rigid mold 20 can be used for finishing (secondary processing). However, finishing (secondary processing) does not carry out the pressing.

Finishing (secondary processing) press forming equipment with a capacity of 1960kN (200 tons). Further, as shown in Fig. 16B, the secondary processing until the height of the press-formed product 57 becomes 80 mm. By this finishing process (secondary processing), the press-formed product 50 having a cross-sectional hat shape becomes a press-formed product 57 having the shape shown in Figs. 16A and 16B. Further, the press forming apparatus which has been used is a general press forming apparatus which does not have a variable mold pad apparatus or the like.

Next, a method of evaluating the rebound of the press-formed product 50 after press-bending (press-molding) and the press-formed product 57 after finishing (secondary processing) will be described.

Fig. 18 is a longitudinal cross-sectional view perpendicular to the longitudinal direction of the press-formed product after the extrusion bending process, and is an explanatory view showing a state in which the wall is lifted (rebounded). In FIG. 18, W _h denotes the vertical when the rebound is not generated and the wall portion 55a of the vertical wall portion 55b spaced, W _h 'represents a vertical wall portion 55a when the springback' spaced from the vertical wall portion 55b 'is, △ W _h represents the difference between W _h ' and W _h . Specifically, as shown in Fig. 18, the intersection of the vertical wall portion 55a and the flange portion 54a is regarded as P, and when the intersection of the vertical wall portion 55b and the flange portion 54b is regarded as Q, the line segment PQ is regarded as W. _h . Further, when the intersection of the vertical wall portion 55a' and the flange portion 54a' is regarded as P', and the intersection of the vertical wall portion 55b' and the flange portion 54b' is regarded as Q', the line segment P'Q' is regarded as W _h '.

W _h ', W _h , and ΔW _h can be obtained as follows. After the extrusion bending process (press molding), the point group coordinate value of the outer surface of the press-formed product 50 was obtained using a non-contact CCD3 dimensional measuring device. Further, the longitudinal section of FIG. 6A viewed from the direction of the arrow A is measured for the interval W _h ' between the vertical wall portion 55a' and the vertical wall portion 55b' in a state in which the rebound occurs. The interval W _h 'comparator (designed shape) of the vertical wall portion and the interval W _h 55a of the vertical wall portion 55b and press-molded product when the CAD data 50 of the design, is obtained _{△ W h = W h' -W} h.

According to the ΔWh obtained in this way, the wall lift (rebound) after the extrusion bending (press molding) was evaluated by the following criteria.

Good (G): ΔW _h is 10 mm or less

Not Bad (NB): △W _h exceeds 10mm and is less than 15mm

Bad (B): △W _h is 15mm or more

Moreover, FIG. 19 is a longitudinal cross-sectional view in the longitudinal direction of the press-formed product perpendicular to the finishing process (secondary processing), and is an explanatory view showing a state in which the wall is lifted (rebounded). In Fig. 19, W _c indicates the interval between the vertical wall portion 55a and the vertical wall portion 55b when no rebound occurs, and W _c ' indicates the interval between the vertical wall portion 55a' and the vertical wall portion 55b' when the rebound occurs. ΔW _c represents the difference between W _c ' and W _c . Specifically, as shown in FIG. 19, when the end portion of the vertical wall portion 55a is regarded as the point R and the end portion of the vertical wall portion 55b is regarded as the point S, the line segment RS is regarded as W _c . Furthermore, if the vertical wall portion 55a 'of the end portion as a point R', the vertical wall portion 55b 'of the end portion as the point S', a line segment R'S 'as W _c'.

W _c ', W _c , and ΔW _c can be obtained as follows. After the finishing processing (secondary processing), the point group coordinate value of the outer surface of the press-formed product 57 is obtained using a non-contact CCD3 dimensional measuring device. And, in the direction of arrow B of FIG. 16A viewed from the longitudinal cross section, with a vertical wall portion measuring the state of the springback of 55a 'and the vertical wall portion 55b' of the interval W _c '. The interval W _c 'CAD data (designed shape) of the vertical wall portion 55a is compared with the vertical wall portion 55b of the spacer 57 W _c product design and press molding, is obtained _{△ W c = W c' -W} c.

According to the ΔWC obtained in this way, the wall lift (rebound) after the finishing processing (secondary processing) was evaluated by the following criteria.

Good (G): ΔW _c is 7 mm or less

Not Bad (NB): △W _{c is} more than 7mm and less than 15mm

Bad (B): △W _c is 15mm or more

Moreover, FIG. 20 is a perspective view showing a press-formed product after finishing (secondary processing), and is an explanatory view showing a state in which waves (rebound) are generated. In Fig. 20, the curved surface of the curved portion 52 of the press-formed product 57 is shown. 60, the state of the wave 61.

Fig. 21A is a perspective view showing a press-formed product after finishing (secondary processing), and is an explanatory view showing a measurement position of a wave (rebound). The generation of the wave 61 is evaluated by the line segment 62 indicated by a broken line in Fig. 21A. Fig. 21B is a graph showing an example of the measurement result of the wave (rebound). In Fig. 21B, the horizontal axis corresponds to the line segment 62 shown in Fig. 21A, and the vertical axis represents the generation condition of the wave 61 (the difference between the measured value and the designed shape value).

The wave 61 of the press-formed product 57 can be evaluated as follows. After the finishing processing (secondary processing), the point group coordinate value of the outer surface of the press-formed product 57 is obtained using a non-contact CCD3 dimensional measuring device. Further, the measurement result of the coordinate value of the line segment 62 in the curved surface 60 is compared with the CAD data (design shape) at the time of designing the press-formed product 57, and the graph shown in FIG. 21B is produced. The absolute value ΔYw of the difference between the maximum value and the minimum value of the graph in the curved surface 60 is obtained as shown in Fig. 21B. On the other hand, the line position 62 of the measurement position of the wave 61 is parallel to the line formed by the top portion 55c of the press-formed product 57 (the cross-sectional shape of the U-shaped portion) and the vertical wall portion 55a, and the distance between the parallel lines is 70 mm.

According to the ΔYw obtained in this way, the wave 61 (rebound) after the finishing (secondary processing) was evaluated by the following criteria.

Very Good (VG): △Yw is 3mm or less

Good (G): ΔYw is 3 mm and 7 mm or less

Not Bad (NB): △ Yw is more than 7mm and less than 15mm

Bad (B): △ Yw is 15mm or more

The results of the rebound evaluation of the press-formed product 50 after extrusion bending and the press-molded product 57 after finishing (secondary processing) are shown in Table 2. On the other hand, after the extrusion bending process and the secondary processing, it was not confirmed that the press-formed product 50 or the press-formed product 57 was damaged by using any of the conditions.

First, the results of the rebound evaluation of the press-formed product 50 after the extrusion bending process will be described. As shown in Table 2, it was confirmed that Examples No. 3 to No. 7 and No. 9 to No. 12 of the present invention were excellent in ΔW _h after extrusion bending, and the wall lift (rebound) was small. . On the other hand, Reference Example No.1, No.2, No.8, No.13, after the extrusion and conventional bending of Example No.14 △ W _h did not further embodiment of the present invention than △ W _h it is good.

Further, according to the comparison of the inventive examples No. 3 and No. 6, the ratio can be confirmed. The embossing force increasing portions 16a to 16f are arranged, and by merely arranging the pressing force increasing portions 16a and 16b, the rebound reducing effect can be further improved. That is, when only the pressing force increasing portions 16a and 16b are disposed, the press dies 25a and 25b are significantly deflected at the end of press forming as compared with the case where the pressurizing force increasing portions 16c to 16f are disposed. As a result, it was confirmed that the rebound of the molded article 50 can be further reduced.

Further, by comparing the examples of the present invention with No. 1 to No. 4 of the reference examples, it was confirmed that the meat thickness H and the meat thickness L should satisfy the above formula 1 or formula 2. These No. 1 to No. 4 change only the meat thickness L of the binder molds 25a and 25b, and the other press molding conditions are the same. On the other hand, in No. 1 to No. 4, although the value of the protruding height G is different, the position of the pressing stroke in which the pressing force starts to increase is 15%. Among these No. 1 to No. 4, No. 1 and No. 2 have a meat thickness L of more than 0.8 × H, and No. 3 and No. 4 have a meat thickness L of 0.8 × H or less. In other words, in No. 1 to No. 4, No. 3 and No. 4, which are examples of Formula 1 or Formula 2, are satisfied, and the rebound can be suitably reduced.

Here, FIG. 22 to FIG. 25 show the surface pressure distribution of the second faces 32a and 32b when the press dies 25a and 25b receive the reaction forces from the pressurizing force increasing portions 16a and 16b at the end of the press forming. These FIGS. 22 to 25 correspond to No. 1 to No. 4 which are examples of the present invention and reference examples. That is, Fig. 22 is a view showing the surface pressure distribution of the second surface of the press mold when the meat thickness ratio L/H of the press mold is 100%. Fig. 23 is a view showing the surface pressure distribution of the second side of the press mold at a weight ratio L/H of the press die. Fig. 24 is a view showing the surface pressure distribution of the second side of the press mold when the meat mold thickness ratio L/H of the press mold is 80%. Fig. 25 is a view showing the surface pressure distribution of the second side of the press mold when the meat mold thickness ratio L/H of the press mold is 70%. In Figures 22 to 25, symbols 71, 72, 73, and 74 are displayed. The area where the surface pressure is the maximum value is shown in the second faces 32a and 32b. Further, in the regions of the symbols 71, 72, 73, and 74, the surface pressures were individually 1.5 MPa, 2.5 MPa, 6.5 MPa, and 8.7 MPa.

As shown in Fig. 22 to Fig. 25, when the meat thickness H is 50 mm, the smaller the thickness ratio L/H, the pressure receiving portions 30a and 30b are provided in the second faces 32a and 32b of the press dies 25a and 25b. The corresponding partial area pressure will be larger. As described above, the flange portions 54a and 54b of the press-formed product 50 are sandwiched between the rigid mold 20 and the second faces 32a and 32b of the die halves 25a and 25b, and the pressing force is applied. Therefore, it is preferable to overlap the portion where the pressing force is particularly increased in the flange portions 54a, 54b when viewed in the pressing direction and the region where the surface pressure becomes large in the second faces 32a, 32b (the pressure receiving portion 30a is provided). Part of the area of 30b).

By comparing the present invention example with the reference examples No. 4 and No. 11 to No. 13, it can be confirmed that the protruding heights G of the pressing force increasing portions 16a and 16b satisfy the above Expression 3. These No. 4, No. 11 to No. 13 change only the pressing stroke position at which the pressing force starts to increase by changing the value of the protruding height G, and the other pressing forming conditions are the same. Among these No. 4, No. 11 to No. 13, the pressing stroke position at which the pressing force starts to increase is No. 11 and the pressing stroke position at which the pressing force starts to increase is 1.8%. On the other hand, in No. 4 and No. 11 to No. 13, the pressing stroke position at which the pressing force starts to increase is No. 4, and the pressing stroke position at which the pressing force starts to increase is No. 12. %. That is, in No. 4 and No. 11 to No. 13, in No. 4 and No. 12, the protruding height G satisfies Expression 3. As described above, in No. 4 and No. 11 to No. 13, it is confirmed that No. 4 and No. 12, which are examples of Formula 3, can be appropriately reduced in rebound.

On the other hand, reference examples No. 1 and No. 2 are as described above in order to The meat thickness L exceeds 0.8 × H, and it is not possible to appropriately reduce the rebound. Reference Example No. 8 is an example in which the rebound thickness cannot be appropriately reduced in order to make the meat thickness L exceed 40 mm. Further, as described above, Reference Example No. 13 is an example in which the pressing stroke position at which the pressing force starts to increase is 1.8%, and the pressing force at the end of the press forming is insufficient, so that the rebound cannot be appropriately reduced. . Since the conventional example No. 14 does not have the pressure receiving portions 30a and 30b and the pressing force increasing portions 16a and 16b, the springback cannot be reduced.

Next, the results of the rebound evaluation of the press-formed product 57 after the finishing processing (secondary processing) will be described. As shown in Table 2, it was confirmed that the ΔW _c and ΔYw of the examples No. 3 to No. 7 and No. 9 to No. 12 of the present invention were excellent after finishing (secondary processing), and the wall was warped. It is quite small with the wave 61. In other words, it has been confirmed that the rebound of the press-formed product 50 after the press bending (press molding) is small, and the press-formed product 57 after the finishing (secondary processing) can improve the dimensional accuracy. This is because the pressing force of the bending portion 52 is increased by the end of the press forming process by the extrusion bending process, and the tensile stress in the longitudinal direction of the press-formed product 50 toward the vertical wall faces 55a and 55b of the curved portion 52 is lowered. Start. As a result, the unevenness of the residual stress in the thickness direction or the in-plane direction of the press-formed product 50 is alleviated, so that the dimensional accuracy of the press-formed product 57 after finishing (secondary processing) can be improved. On the other hand, Reference Examples No. 1, No. 2, No. 8, No. 13, and Conventional Example No. 14 are ΔW _c and ΔYw after secondary processing, which are not ΔW of the present invention example. _c and ΔYw are good. As described above, it has been confirmed that when the rebound of the press-formed product 50 after the extrusion bending process is large, even if the finishing process (secondary processing) is performed, the dimensional accuracy of the press-formed product 57 is not suitably improved.

(Example 2)

Fig. 26 is a view showing the arrangement position of the pressure receiving portion and the pressing force increasing portion of the press forming mold. As shown in the figure, the positions of the pressure receiving portions 30a, 30b, 30g to 30j and the pressing force increasing portions 16a to 16f are changed, and the blank 5 is subjected to extrusion bending (press molding). Specifically, a high-tensile steel sheet having a thickness of 1.0 mm and a tensile strength of 590 MPa was used as a material, and the laser was cut into the same shape as that of the above-described Example 1 to obtain a blank 5. The blank 5 is subjected to extrusion bending (press molding) to have a shape (cross-sectional hat shape) as shown in FIGS. 6A and 6B. Table 3 shows a combination of the pressure receiving portions 30a, 30b, 30g to 30j and the arrangement positions of the pressing force increasing portions 16a to 16f. For example, the press molding die of the invention No. 16 is the same as the press molding die 2 of the invention example No. 5 of the first embodiment except that the meat thickness H, the meat thickness L, and the meat thickness ratio L/H are removed. The load (reaction force) applied to the press dies 25a and 25b by the circular spring unit of the pressurizing force increasing portions 16a to 16f is 150 kN. Further, the protruding height G is 19 mm. The pressing stroke distance PS from the press forming start point to the press forming end point was 60 mm. That is, the forming start position of the pressing stroke when the forming blank 5 is pressed is regarded as 100%, and when the forming end position of the pressing stroke is regarded as 0%, the pressing stroke position at which the pressing force starts to increase is 6.7%. Further, after the extrusion bending process, finishing processing (secondary processing) is performed. The conditions of the extrusion bending process, the conditions of the secondary processing, and the evaluation method of the rebound were the same as in the above-described first embodiment.

The rebound evaluation results of the press-formed product 50 after extrusion bending and the press-molded product 57 after finishing (secondary processing) are shown in Table 4. On the other hand, after the extrusion bending process and the secondary processing, it was not confirmed that the press-formed product 50 or the press-formed product 57 was damaged under any of the conditions.

As shown in Table 4, it was confirmed that ΔWh after the extrusion bending process of the present invention No. 16 and ΔW _c and ΔYw after the finishing process were all good, and the rebound was small. In the example of the present invention, the pressure-receiving portion 30b is disposed so as to overlap the portion of the curved inner portion 6b, and the inner portion 6b of the curved portion is convex with respect to the press-formed press-formed product 50. The inside of the edge portions 54a and 54b is a curved outer side portion 6a having a maximum thickness, and the thickness is reduced by more than 0% and 97% or less. That is, the present invention example No. 16 shows a very difficult case in the conventional press forming mold 91, which is such that the pressing force of the curved inner side portion 6b which must increase the pressing force at the end of the press forming can be locally and concentratedly increase.

On the other hand, in Reference Example No. 15 and No. 17 to No. 20, ΔWh, ΔW _c , and ΔYw were not better than Example No. 16 of the present invention. As shown in Table 4, the reference examples No. 15 and No. 17 to No. 20 are arranged such that the pressure receiving portions 30a and 30g to 30j are not in contact with the curved inner portion 6b of the plate thickness reducing portion, and the curved outer portion is formed. 6a or an example in which at least a part of the straight portions 6c to 6f overlap. Therefore, the pressing force of the curved inner side portion 6b which must increase the pressing force at the end of the press forming cannot be appropriately increased. In general, in the press-formed product 57, it is required that the entire area of the press-formed product 57 is within a tolerance range. In other words, even if the press-formed product 57 having a size outside the allowable range is used, for example, the press-formed product 57 of Reference Examples No. 15 and No. 17 to No. 20 is not suitable.

As described above, it can be confirmed that when the pressing force of the plate thickness reducing portion which is required to increase the pressing force is increased at the end of the press forming, the press-formed product 50 after the bending process and the finishing process (secondary processing) are confirmed. The dimensional accuracy of the press-formed product 57 can be suitably increased.

Industrial availability

As described above, according to the above aspect of the invention, the pressure receiving portion is provided in one portion of the press mold, and the pressing force increasing portion is provided in one portion of the punch mold. The pressure receiving portion is in contact with the pressing force increasing portion at the end of press forming, and the die is elastically deformed. As a result, the pressing force generated from the pressing force increasing portion can be sufficiently conveyed to the portion of the blank which needs to increase the pressing force at the end of the press forming. That is, even if the press-formed product has an extended flange deformation region in addition to the contraction flange deformation region, the rebound of the press-formed product can be effectively reduced. Therefore, the industrial availability is quite high.

1‧‧‧ Press forming mould

10‧‧‧punch mould

12‧‧‧ Punch Department

14‧‧‧ Template Department

16b‧‧‧Pressure force increase section (round spring unit)

20‧‧‧Molding

25a, 25b‧‧‧Pressure mould

30b‧‧‧pressure department (groove)

31a, 31b‧‧‧ first side

32a, 32b‧‧‧ second side

33a, 33b‧‧‧ third side (side)

Claims (6)

A press forming mold comprising: a punching die having a punching portion and a template portion for transferring a shape to a blank; a rigid die paired with the punching die and facing the punching portion; The mold has a first surface that faces the template portion and that is in contact with the template portion at the end of press molding, a second surface that faces the rigid mold and that sandwiches the blank with the rigid mold, and a third surface that is disposed between the first surface and the second surface and that faces the punching portion, and the die is disposed between the third surface and the punch portion through a gap; and the press molding die The pressure receiving portion includes a groove portion on the first surface of the press mold, and a press force force applying portion that protrudes toward the pressure receiving portion on a surface of the template portion that faces the first surface. And when the press molding is performed in the press direction, the reaction force is generated in the opposite direction, and the press mold is not a split type but an integral type, and the pressure receiving portion is formed by the groove portion, and the groove portion is positioned. prior to When the flesh nip in mm as a mold to L, and the removed portion of the groove and the contact with the nip position of the blank in the mold in mm as a minimum flesh H, the die nip The following formula 1 or formula 2 is satisfied, and the protruding height of the pressurizing force applying portion is regarded as G in units of mm, and the pressing stroke distance from the press forming start point to the end of the press forming is regarded as a unit mm. In the case of PS, the aforementioned protruding height G of the pressing force force adding portion satisfies the following formula 3, 40 ≦ H ≦ 50, 20 ≦ L ≦ 0.8 × H. . . (Formula 1) 50<H≦80, 20≦L≦40. . . (Formula 2) 0.02 × PS + H - L ≦ G ≦ 0.3 × PS + H-L. . . (Formula 3). The press-molding mold according to the first aspect of the invention, wherein the pressure-receiving portion and the pressing force-adding portion are removed from the press-molding mold, and the thickness of the flange portion of the press-formed product is maximized. When the area is the largest part of the thickness of the sheet and the area where the thickness is more than 0% and 97% or less with respect to the maximum thickness of the sheet thickness is regarded as the sheet thickness reducing portion, the above-mentioned pressing direction is observed. The pressing portion overlaps with a portion of the region corresponding to the thickness reduction portion of the blank. The press-molding mold according to claim 1 or 2, wherein a part of the boundary defining the pressure receiving portion is the groove portion. The press-molding mold according to claim 1 or 2, wherein the pressurizing force applying portion has an elastic body that imparts the aforementioned reaction force. The press-molding mold according to claim 4, wherein the elastic body is at least one of a circular spring, a coil spring, and a rubber. A method for producing a press-formed article, which comprises pressing a shape forming mold according to claim 1 or 2, which comprises: When the forming start position of the pressing stroke in the press forming of the blank is 100%, and the forming end position of the pressing stroke is regarded as 0%, the pressing stroke is 2% or more and 30% or less. At the end of the press forming until the forming end position, the pressing force for a part of the aforementioned blank in the press forming is added.