TW201341079A - Method for manufacturing closed structure parts and apparatus for the same - Google Patents

Abstract

The invention provides the method of manufacturing a closed structure parts by forming a closed structure with a bottom portion B1 bended along a length direction from a plate-shape process material B. The method includes: a first forming step of forming a plurality of first out-of-plane deformation portions 10, including a concave-shape or a convex-shape respectively, along the length direction of at least the bottom portion B1 of the process material B, forming a bending portion B4, and a second forming step of pressing a punch 3 into a die 5 in a condition that a pad 4 and the punch 3 clamp the bottom portion B1 of the process material B, in order to crush and bend the first out-of-plane deformation portions 10 and form the bending portion.

Description

Method and device for manufacturing closed-section structural parts

The present invention relates to a technique in which a flat-shaped processed material (base) is formed into a curved shape in which a bottom surface portion is curved in a longitudinal direction to produce a pressed portion having a closed-sectional structure.

In the field of automobiles, home appliances, construction, and the like, in order to manufacture a pressed part of a closed-section part, each of the both ends of the cross-section of the part has a flange and a pair of sections are substantially After the two parts of the shape of the word are respectively formed, the respective parts are joined by a flange portion by continuous welding such as spot welding or laser to obtain a closed-section part as a product.

In order to achieve low-cost manufacturing, weight reduction, impact characteristics, and improvement in rigidity performance, the production of the pressed component having such a closed-section structure has been proposed to form a closed portion having a polygonal cross section by one base material by press molding. The method of facial products.

Here, Patent Document 1 discloses a method in which a central portion of a flat material is supported by a pad, and an end portion of the material is pressed to have a curvature in a plan view and a lower side of the side wall surface when viewed from the side. The shape of the flange face. Further, Patent Document 1 describes that a convex bead which is convexly convex is provided on a side wall surface of a press-formed body, and a concave bead is provided on a flange surface directly below the front surface of the press-formed body. The line length difference at the end of the material is substantially completely eliminated, thereby suppressing wrinkles in the formed portion.

Further, Patent Document 2 discloses a press forming apparatus for obtaining a molded article from a flat material sheet, the molded article being included in the long A curved portion that is curved in the radial direction, an expanded portion that extends from the curved portion in the longitudinal direction, and a flange that extends the side of the curved portion and the expanded portion. The press forming apparatus includes a pressing portion for pressing an edge portion of a material sheet constituting a flange of the curved portion, and includes a driving mechanism for squeezing the expanding portion forming mold and the expanding portion forming mold The pressing portion moves in a direction to cancel the residual stress generated on the flange surface of the curved portion.

[Previous Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open Publication No. 2010-115674

[Patent Document 2] Japanese Patent Laid-Open Publication No. 2008-200688

In the technique described in Patent Document 1, when the pressed portion having a curved surface is formed, the base flange corresponding portion line length (D1) is compared with the corresponding portion line length (D2) after molding, and then the performance is expressed. In the case where the line length difference before and after the formation occurs: when the value of D1-D2 is positive, that is, when the line length before molding is longer than the line length after molding, wrinkles or buckling are likely to occur. Further, in order to eliminate the line length difference, Patent Document 1 proposes a technique of imparting a convex bead which is convex in a convex shape to a side wall portion, and a concave bead which is recessed into a concave shape is provided to a flange surface directly below the flange portion. .

However, in the technique described in Patent Document 1, in the structure of the mold, only the side wall portion of the component and the flange portion connected to the side wall portion are provided with the uneven shape. Therefore, the technique of Patent Document 1 can be applied only to a member having a curvature in a plan view (that is, a pressed member having a linear shape when viewed from the side). Further, there is a problem that it cannot be applied to a closed-section member formed by one base material.

Further, the technique described in Patent Document 2 is a method in which a part having a curvature in a plan view is formed while applying a compressive load to the longitudinal direction of the part during press forming, thereby reducing residual stress generated on the flange surface. Improve dimensional accuracy. In the technique described in Patent Document 2, there is a problem that it can be applied only to a member having a curvature in a plan view (that is, a pressed member having a linear shape when viewed from the side).

As described above, in the prior art, it is not possible to easily press-form a closed-section portion in which at least the bottom surface portion of the press-worked product has a curved curved shape.

The present invention has been made in view of the above-described problems, and it is an object of the invention to reduce the manufacturing cost by reducing the number of molding steps or the number of molds, and to manufacture a closed section having a curved curved surface having a curved surface at a high dimensional accuracy. The pressed parts of the structure.

In order to solve the problem, the invention according to claim 1 of the present invention is a method for producing a closed-section structural member, in which a flat-shaped processed material is formed into a closed-sectional structure in which a bottom surface portion is curved in a longitudinal direction to produce a closed structure. The method of the surface structure part includes a first molding step of forming a plurality of first surface outer deformation portions each including a concave shape or a convex shape on at least a bottom surface portion of the processed material along the longitudinal direction, and forming And a second forming step of pressing the punch between the dies by a state in which the spacer and the punch sandwich the bottom surface portion of the processing material, thereby using the spacer and the punch The first outer surface deforming portion crushes and bends the bent portion.

According to the invention of the second aspect of the invention, the flat-shaped processed material is formed into a closed-sectional structure, and the closed-sectional structure includes the bottom surface portion, and the configuration is the same as the configuration described in the first aspect. a left and right side wall portions on the left and right sides of the bottom surface portion, and a pair of joint end portions respectively connected to the left and right side wall portions; in the first molding step, the side wall portion positions respectively include a concave shape or a convex shape The second out-of-plane deforming portion is formed in plurality along the longitudinal direction together with the first out-of-plane deforming portion, and a bent portion is formed at a boundary portion between the bottom surface portion and the side wall portion; in the second forming step The second outer deformation portion is crushed by the side surface of the punch and the side surface of the mold.

According to the invention of the third aspect of the invention, in the first aspect of the invention, after the first molding step is completed, and before the bending portion is formed in the second molding step, the bottom surface portion of the processed material is applied. Set the bulk head.

According to the invention of the fourth aspect of the invention, the apparatus for manufacturing a closed-section structure is formed by molding a flat-shaped processed material into a closed-sectional structure in which the bottom surface portion is curved in the longitudinal direction, and includes: The pressing mold includes an upper mold and a lower mold, and the upper mold and the lower mold form a plurality of first outer surface deformation portions each including a concave shape or a convex shape at a position of at least a bottom surface portion of the processed material along the longitudinal direction And forming a flexure; and a shim and a punch for clamping the bottom surface portion of the processed material to crush the first outer deformed portion; and In the mold, the bent portion is bent and formed by press-fitting the punch in a state where the spacer and the punch are sandwiched between the bottom surface portions of the processed material.

According to the invention of the fourth aspect of the invention, in the configuration of the fourth aspect of the invention, the flat-shaped processed material is formed into a closed-sectional structure, and the closed-sectional structure includes the bottom surface portion. And a pair of left and right side wall portions on the left and right sides of the bottom surface portion, and a pair of joint end portions respectively connected to the left and right side wall portions; the upper mold and the lower mold are configured such that the position of the side wall portion is The second outer surface deformation portion including the concave shape or the convex shape is formed in plurality along the longitudinal direction together with the first outer surface deformation portion, and the bending portion is formed at the boundary portion between the bottom surface portion and the side wall portion. Further, the second outer surface deformation portion is crushed by the punch side surface and the mold side surface.

According to the invention of the fourth aspect of the invention, in the fourth aspect or the fifth aspect of the invention, the curved portion is bent and formed by sandwiching the bottom surface portion of the processed material with a gasket and a punch, and the processed material is A partition wall is provided on the bottom surface portion.

According to the invention of the first aspect or the fourth aspect, the first outer surface deformation portion is formed in the longitudinal direction on the bottom surface portion to obtain a line length in the longitudinal direction, and then a punch having a curved shape at the bottom of the punch is used for press forming. A curved shape that is curved at the bottom surface. Thereby, the first outer surface deforming portion is crushed to obtain the longitudinal direction extension caused by the bending of the bottom surface portion, and the shape of the bottom surface portion can be processed into the target curved surface shape.

As a result, it is possible to reduce the manufacturing cost by the reduction of the number of molding steps or the number of the molds, and it is possible to manufacture a closed-sectional structure member having a curved curved shape on the bottom surface portion with good dimensional accuracy.

Further, in the invention of the second aspect or the fifth aspect, the second outer surface deformation portion is further provided in the side wall portion, and the second outer surface deformation portion is crushed to obtain the extension of the side wall portion, thereby enabling further processing. The target curved surface shape of the pressed part of the closed-section structure.

Further, according to the invention of claim 3 or 6, the partition wall can be easily provided in the pressed part of the closed cross-sectional structure by providing the partition wall before the forming of the closed cross section.

Next, an embodiment of the present invention will be described with reference to the drawings.

(First embodiment)

First, the first embodiment will be described.

As the flat processing material B (also referred to as a base), for example, a metal veneer or a metal having a base shape corresponding to the shape of a target molded article may be subjected to shear processing or cutting. board. Further, the metal veneer may be a veneer such as a hot-rolled steel sheet or a cold-rolled steel sheet, or may be subjected to surface treatment (such as electrogalvanizing, hot-dip galvanizing, or aluminum plating). The steel plate includes various metals such as stainless steel (SUS), aluminum, and magnesium. In the case of a hot-dip galvanized steel sheet, the alloying treatment may be performed, and further, the plated steel sheets may be further subjected to surface treatment (organic film treatment or the like) after plating. Furthermore, in the case of using a steel plate as a metal veneer, it is of course possible to use a soft steel. For the plate, a hard steel plate (high tensile steel plate or ultra high tensile steel plate) may be used, and the press forming of the present invention is suitable for forming a high tensile steel plate or an ultra high tensile steel plate.

Further, the press forming of the present invention is carried out by using the above-mentioned flat shaped processing material B, and the cross-sectional shape (closed cross-sectional shape) of the molded article after molding has, for example, a quadrangular shape, a hexagonal shape, an octagonal shape or the like. a cross-sectional shape of a polygon (including a substantially polygonal shape approximated thereto), or a closed shape as shown by a circular or elliptical shape having a curvature of a section (including a substantially circular shape approximate to the shape, a substantially elliptical shape) Section shape. Among these, the pressed part after molding has a curved cross-sectional structure that is curved toward the lower side in the longitudinal direction by molding.

Further, the closed-sectional structure of the present invention has a joint end portion B3 (also referred to as a welded end portion in the present specification) which is finally used for joining the ends. The joint end portion B3 is not limited to welding such as laser welding or arc welding, and can be appropriately joined by joining of rivet joints, bolt joints, adhesives, or the like. In the following examples, the case of joining by welding is exemplified.

In the following description, as shown in (a) to (b) of FIG. 1 , the pressed portion of the closed-sectional structure in which the flat-shaped processed material B is formed in the present embodiment is exemplified as a cross-sectional shape of approximately four. The case of the edge. Among them, as shown in FIG. 1( a ), the shape is curved in the longitudinal direction.

(device configuration)

In the manufacturing apparatus, the flat-shaped processed material B is formed into a closed-sectional structure including the bottom surface portion B1 formed on the central portion side in the width direction of the processed material B, and the width of the bottom surface portion B1. direction a pair of left and right side wall portions B2 on both sides, and a pair of welded end portions B3 (flange portions) respectively connected to the left and right side wall portions B2, and the side wall portions B2 are press-formed to protrude toward the lower side along the longitudinal direction Curved curved shape (refer to (a) to (b) of Fig. 1).

This manufacturing apparatus includes a mold for pressing for the first molding step and a mold for bending for the second molding step.

The mold for pressing described above includes the lower mold 1 and the upper mold 2 which are press-formed by sandwiching the flat processing material B as shown in (a) to (c) of FIG. 2 as a schematic view.

The upper surface of the lower mold 1 constitutes a press forming surface that is open to the upper side. That is, the press forming surface has a substantially upward cross section of the recess In the shape of a word, the center portion in the width direction is the bottom portion forming portion 1a, and the left and right portions of the bottom portion forming portion 1a are the side wall forming portions 1b. The outer side of the side wall forming portion 1b has a rising surface 1c for forming a welded end portion including a flange.

As shown in FIG. 2(c), the bottom surface forming portion 1a is formed with a plurality of concavo-convex shapes that are undulating along the longitudinal direction when viewed from the side. Each of the concave shape and the convex shape has an arc shape when viewed from the side, and the adjacent concave shape and convex shape are connected by a smooth curved surface so that the curvature is not steep. This concave shape or convex shape is a portion that forms the press-molding surface of the first outer surface deformation portion 10.

Each of the concave shapes or the convex shapes extends in the width direction, and is continuously formed at the position of the side wall forming portion 1b. Each of the concave or convex shapes formed in the side wall forming portion 1b is a portion that forms a press forming surface of the second outer surface deforming portion 11. Each concave shape or convex shape formed on the side wall forming portion 1b It is assumed that the width in the longitudinal direction is smaller toward the width direction.

Further, a steep portion is formed at a boundary portion between the bottom surface portion molding portion 1a and the side wall molding portion 1b, and a bending portion B4 is formed at the boundary portion.

Further, the side wall forming portion 1b is formed obliquely with respect to the bottom surface portion forming portion 1a.

Further, the upper mold 2 has a shape that is inserted into the press-molding surface of the lower mold 1, and the left and right end surfaces of the lower surface and the width direction are press-molded surfaces. Further, the press-formed surface including the lower surface of the upper mold 2 is in the shape of the upper surface (press-molded surface) of the lower mold 1 which is photographic. That is, a concave bottom surface forming portion is formed in the center portion in the width direction, and side wall forming portions are formed on the left and right sides.

Further, in a state in which the processing material B is inserted between the lower mold 1 and the upper mold 2, the upper mold 2 is inserted into the lower mold 1, and press forming of the processed material B is performed.

Further, the mold for bending molding includes a punch 3, a spacer 4, and a pair of dies 5 as shown in (a) to (c) of FIG. 3 as a schematic view.

The cross-sectional shape of the extruded portion of the punch 3, that is, the cross-sectional shape of the lower end portion, and the bottom surface portion B1 after the lower end surface 3a is formed into a closed-sectional structure have the same shape. In other words, as shown in FIG. 4, the lower end surface 3a has a gentle curved surface shape that protrudes downward in the longitudinal direction. Further, the side surface shape of the extruded portion of the punch 3 is a flat shape.

Further, the spacer 4 and the punch 3 are arranged to face each other in the vertical direction, and the upper surface 4a is shaped to follow the lower end surface of the punch 3.

Further, the pair of dies 5 are spaced apart from the width of the bottom surface portion B1. Interval and opposite. The pair of dies 5 are press-fitted into the punch 3, and are bent in a direction in which the left and right side wall portions B2 approach, with the bent portion B4 as a fulcrum and curved so that the side wall portion B2 is bent. The shape of the pair of dies 5 in the longitudinal direction is a shape that follows the shape of the formed part.

(Production method)

Next, a method of manufacturing a closed-section structure member using the above-described manufacturing apparatus will be described.

In the present embodiment, the processed material B including the flat metal plate is press-formed into the pressed portion of the target closed-sectional structure by press molding in two steps. Then, a solder assembly step is performed.

Here, the steps of the present embodiment will be described on the premise that the front pillar R/F of the automobile is manufactured. The part manufacturing step includes the following two steps: (1) forming step, and (2) welding assembling step.

(1) Forming step

The forming step is divided into a first forming step and a second forming step.

(1-1) First forming step

In the step of forming the bottom surface portion B1 and the side wall portion B2 of the flat material B (base), the first and second outer surface deformation portions 10 and 11 are formed into a concave-convex shape, and the bending portion is formed. B4.

In other words, as shown in (a) to (c) of FIG. 2, in a state in which a flat material B is inserted between the lower mold 1 and the upper mold 2 (Fig. 2 (a)), the lower mold 1 is oriented. The upper mold 2 is inserted, whereby press forming is performed ((b) of Fig. 2).

At this time, as shown in FIG. 5( a ), the bent portion B4 is formed at the boundary portion between the bottom surface portion B1 and the side wall portion B2, and is formed to be opposed to the bottom surface portion B1. The shape in which the left and right side wall portions B2 are lifted upward obliquely upward.

Further, the uneven shape of the bottom surface molding portion 1a and the side wall molding portion 1b is transferred to the processing material B, and the first surface outer deformation portion 10 including the concave shape or the convex shape at the bottom surface portion B1 is along the longitudinal direction. A plurality are formed ((a) of Fig. 5). At the same time, a plurality of second outer surface deformation portions 11 each including a concave shape or a convex shape are formed along the longitudinal direction at positions on the right and left side wall portions B2 located on the left and right sides.

Here, it is preferable that each of the first out-of-plane deformation portions 10 is connected to the second surface outer deformation portions 11 located on both sides thereof in the width direction of the workpiece B. Further, each of the first out-of-plane deforming portions 10 of the present embodiment extends in the width direction. That is, the boundary of the adjacent first outer surface deformation portion 10 extends in the width direction.

Here, the larger the number of the first outer surface deformation portions 10 formed along the longitudinal direction, the more the material can be uniformly extended in the longitudinal direction. Therefore, it is preferable to set the number of the first surface deformation portions 10 to six or more, for example, depending on the degree of bending toward the lower side.

In addition, the second outer surface deformation portion 11 is arranged in the longitudinal direction so that the line length along the longitudinal direction of the side wall portion B2 is smaller as it goes away from the bottom surface portion B1, and the second outer surface deformation portion is set in advance. The shape or number of 11.

In other words, stretching and protrusion molding are performed so that the shape after molding becomes the length of each section of the final shape of the part. Further, the first and second outer surface deformation portions 10 and 11 are formed in order to reduce the length difference between the upper and lower surface lines when the curved surface in the vertical direction is observed on the side surface or to zero.

(1-2) Second forming step

Then, the undulating uneven surface (the first surface outer deforming portion 10) of the panel bottom surface portion B1 formed in the first forming step is sandwiched between the spacer 4 and the punch 3, and the spacer 4-punch 3 is interposed. The load is applied while pressing the punch 3 between the pair of dies 5. The load at this time can be fixed or variable.

At this time, as shown in (a) of FIG. 3 and (b) of FIG. 3, by applying a load between the spacer 4 and the punch 3, the first one is crushed as shown in FIG. 5(b). The out-of-plane deformation portion 10 is formed into a shape that follows the molding surface of the punch 3, that is, a shape that is convex toward the lower side and curved in the longitudinal direction.

Further, as shown in Fig. 3 (b) → Fig. 3 (c), the second outer surface deformation portion 11 of the side wall portion B2 is crushed while pressing the punch 3 between the dies 5, The side wall portion B2 stands upright as a standing wall, and is closed as shown in FIG. 5(c).

(2) Welding assembly steps

The side surface of the press-formed part that has been subjected to the closed cross-section is a projection of the upper surface, and is joined by continuous welding such as laser welding or arc welding.

(effect and other)

In order to impart a curved shape to the bottom of the punch, that is, the pressed part after molding in a side view is a curved shape, in the first forming step, as shown in FIG. 5( a ), by press forming, and by press forming The first and second outer surface deformation portions 10 and 11 including the undulating concave-convex shape and the like are provided.

Next, in the second forming step, the first 3 is formed by the punch 3 and the die 5 having the curved surface of the final shape as shown in (a) to (c) of Fig. 3 . The shaped article formed in the forming step is shaped. In the second forming step, the undulating uneven surface (the first outer surface deforming portion 10) of the panel bottom surface portion B1 formed in the first molding step is sandwiched between the spacer 4 and the punch 3, and the spacer 4 is attached. The punch 3 is pressed into the mold 5 while the load is applied. At this time, the second outer surface deformation portion 11 including the uneven portion on the side surface portion of the panel is crushed by the side surface of the die 5 and the side surface of the punch 3, and the side wall portion B2 is raised as a vertical wall to be closed ( (b) of FIG. 5 and (c) of FIG. 5 .

When the punch 3 reaches the bottom dead center, the upper side when the component is viewed from the side is abutted against the other end surface in the slit (not shown) provided in the punch 3, and is closed (Fig. 3 (c)) .

When the cross-sectional shape is changed, the shape of the upper surface is changed so as to be wound around the punch 3 when viewed from the side, but a slit (not shown) is provided at the support portion of the punch 3, so that the processed material does not face the punch. The support of 3 causes interference. Further, when the molded part is pulled out from the punch 3, the latch (not shown) having a gate-like structure located at the end surface of the punch 3 in the longitudinal direction is removed, and the punch 3 is pulled out in the longitudinal direction.

Here, as shown in FIGS. 6( a ) to 6 ( c ), a pair of joint faces B 5 may be formed in advance on the workpiece B. By the press molding of this embodiment, it is possible to accurately arrange the pair of joint faces B5 in the closed cross-sectional structure after press forming.

As described above, in the method of forming according to the present invention, it is possible to manufacture a press-shaped pressed part with high precision from one base material. As a result, by reducing the number of molds and eliminating the need for an assembly step, the effect of simplifying the manufacturing steps can be achieved, the cost can be greatly reduced, and the weight can be reduced without flangering.

In the first forming step, the first outer surface deforming portion 10 is formed in the longitudinal direction in the longitudinal direction of the bottom surface portion B1 to obtain a line length in the longitudinal direction, and then the punch 3 having a curved shape at the bottom of the punch is pressed. It is formed into a curved shape in which the bottom surface portion B1 is curved.

At this time, by extending the first outer surface deformation portion 10, the longitudinal direction extension due to the bending of the bottom surface portion B1 is obtained, and the shape of the bottom surface portion B1 can be processed into a target curved surface shape. As a result, it is possible to reduce the manufacturing cost by the reduction of the number of molding steps or the number of the molds, and it is possible to form the pressed portion of the closed-surface structure in which the bottom surface portion B1 has a curved curved shape with good dimensional accuracy.

Further, the second outer surface deformation portion 11 is provided in advance in the side wall portion B2, and the second outer surface deformation portion 11 is crushed to obtain the side wall portion B2, whereby the pressed portion of the closed cross-sectional structure can be further processed. The target bends the shape.

Here, it is preferable that the shape of the first outer surface deformation portion 10 and the shape of the boundary portion of the first outer surface deformation portion 10 are formed so as not to have a steep curvature along the longitudinal direction and the width direction. The same applies to the second out-of-plane deforming portion 11.

Furthermore, in the above-described embodiment, the first outer surface deformation portion 10 is formed into a shape that is corrugated along the longitudinal direction, that is, a shape in which the concave shape and the convex shape are continuously repeated, but the first The 1 out-of-plane deformation portion 10 is not limited to this. For example, the first out-of-plane deformation portion 10 may be formed only in a concave shape or only in a convex shape. Preferably, the boundary portion of the first out-of-plane deforming portion 10 with respect to the bottom surface portion B1 is preferably as described above. The minute shape is formed into a curved shape so as not to have a steep portion along the longitudinal direction and the width direction.

(Second embodiment)

Next, a second embodiment will be described with reference to the drawings. In addition, the same configurations as those of the above-described first embodiment will be described with the same reference numerals.

The basic configuration of this embodiment is the same as that of the above-described first embodiment, as shown in Figs. 7(a) to 7(d). However, it differs in that the partition wall 16 is provided after the forming of the first forming step.

That is, a partition wall setting step is provided between the first forming step and the second forming step.

Next, the procedure of this embodiment will be described.

(first forming step)

The first molding step is the same as that of the first embodiment described above. However, as shown in FIG. 7( a ), a slit-shaped partition wall providing hole 15 is formed at a position outside the longitudinal direction of the position at which the first surface outer deforming portion 10 is formed.

Further, before the second molding step is performed, the partition wall installation step described below is carried out. Further, the treatment of the partition wall may be performed in the second forming step. In this case, the treatment of the partition wall may be performed until the bending portion B4 of the second molding step is formed before the bending.

(wall setting steps)

Here, the partitioning wall 16 shown in Fig. 8 is prepared by processing the other base material separately from the processing of the above-described processed material B. The partition wall 16, as shown in Fig. 8, includes a partition wall body and an insert piece 16d. The partition wall main body includes a rising portion 16a that is vertically erected by the lower end abutting against the bottom surface portion B1, and a left-right portion that is connected to the side surface of the rising portion 16a and that intersects the surface of the rising portion 16a and protrudes in the lateral direction. Side panel portions 16b, 16c. The left and right side panel portions 16b and 16c can abut against the side wall portion B2. Thus, the partition wall body becomes substantially as viewed on the upper surface. Word shape. Further, a bottom plate extending rearward from the lower end portion of the rising portion 16a is included. The insertion piece 16d which is bent downward at both end portions in the width direction of the bottom plate protrudes downward. The partition wall 16 of the present embodiment has the above configuration and can be processed by a single metal plate.

Further, the processed material B formed in the first forming step described above is attached to the mold set for partition wall installation, and the partition wall 15 is provided for the partition wall of the processed material B, and the insert piece 16d is inserted from the upper side and the partition wall 16 is inserted. It is attached to the bottom surface portion B1 ((c) of Fig. 7). At this time, the partition wall installation hole 15 is located on the outer side in the longitudinal direction from the position where the spacer for the partition wall and the punch are sandwiched. In the mold configuration shown in (a) to (d) of FIG. 7, the case where the installation process of the partition wall 16 is performed in the second molding step is exemplified.

By inserting the insertion piece 16d into the partition wall providing hole 15, the mounting position of the partition wall 16 is positioned, and the partition wall body is in a state of standing upright with respect to the bottom surface portion B1.

The punch for the partition wall is lowered from this state, and the insert piece 16d which protrudes downward from the lower surface of the bottom surface portion B1 is bent by 90 degrees toward the bottom surface portion B1 side, thereby performing caulking. Thereby, the partition wall 16 is provided. Then, the mold set which is the second forming step of the next step is moved by a robot or the like.

Here, a part of the die surface of the mold for providing the partition wall includes an inclined surface 17 as shown in FIG. 9, and the inclined surface 17 abuts against the lower end of the insert piece 16d which is lowered from the upper side from the lower side. When the lower end of the insertion piece 16d abuts against the inclined surface 17, the insertion piece 16d is bent inward by the inclined surface 17, and is bent 90 degrees toward the bottom surface portion B1 side as described above.

(second forming step)

The second molding step is the same as that of the first embodiment described above.

In other words, the undulating uneven surface (the first surface outer deforming portion 10) of the bottom surface portion B1 formed in the first forming step is sandwiched between the spacer 4 and the punch 3, and the spacer 4-punch 3 is given between the spacers The load is pressed into the mold 5 while being pressed. Further, the first surface outer deformation portion 10 formed on the bottom surface portion B1 is crushed between the spacers 4-punch 3, and the uneven portion of the panel side surface portion is formed between the side surface of the die 5 and the side surface of the punch 3 ( The second out-of-plane deforming portion 11) is crushed and the side wall portion B2 is raised to close the cross section. At this time, the side panel portions 16b and 16c of the partition wall 16 abut against the side wall portion B2, whereby the side panel portions 16b and 16c also serve as a part of the side surface of the punch 3.

Further, the punch 3 has a shape in which a hole is formed at the position of the partition wall 16, thereby preventing a load from being applied to the partition wall body.

Here, as described above, the bending process of the insertion piece 16d may be simultaneously performed during the processing in the second molding step.

(welding assembly step)

In the same manner as in the first embodiment, the protruding portion of the upper surface when the side surface of the molded product having the closed section is observed is subjected to laser welding or arc welding. Bonding is continued by continuous welding such as spot welding or spot welding.

Further, in the present embodiment, the bent insertion piece 16d of the partition wall 16 to be provided may be joined to the press-formed product which is a molded part which is a closed section by welding or an adhesive, or may be directly riveted. status.

Here, as shown in (a) to (d) of FIG. 10, a pair of joint faces B5 may be formed in advance on the workpiece B. According to the press forming of the present embodiment, the pair of joint faces B5 can be arranged to face each other with high precision in the closed cross-sectional structure after press forming.

(effect and other)

In addition to the operational effects described in the first embodiment, the following effects are obtained in the present embodiment.

In other words, in the same manner as in the first embodiment, it is possible to manufacture a press-shaped member having a curved cross-sectional structure from one base material. As a result, the number of molds is reduced, and the assembly step is not required, so that the effect of simplifying the manufacturing steps can be achieved, the cost can be greatly reduced, and the weight can be reduced without flangering.

Further, as described above, the partition wall 16 is provided before the bending portion of the second forming step is bent and formed. Thereby, the partition wall 16 can be attached to the main body of the press member without forming an opening for mounting the partition wall 16 later. As a result, the performance of the body of the pressed part is not impaired, and the number of manufacturing steps can be reduced, thereby reducing the cost.

[Example 1]

Next, an example based on the above first embodiment will be described.

"Applicable materials (steel grade, composition, size, etc.)"

Shape of the object after forming: on the front side of the closed section The section of the R/F model is set to 40 mmH × 30 mmW L = 300 mm. In the meantime, as described in the embodiment, a pressed member having a closed-sectional structure having a curved shape bent downward is formed.

First, the common conditions are explained.

"Use steel plate"

The material has a tensile strength of 980 MPa (alloyed hot-dip galvanized (two-sided)), a plate thickness of 1.2 mm, and a plating adhesion (single side) of 45 g/m ² .

"Welding method"

The welding in the welding assembly step is a yttrium aluminum garnet (YAG) laser welding.

Welding conditions set to welding speed: 1500 mm/min

YAG laser output: 3.5 kW

Focusing diameter: 2 mm.

In the following three cases, the following three conditions were used to manufacture the closed-section structural parts.

(first example)

This first example employs press forming as shown in the above (a) to (c) of Fig. 2 .

In the first molding step, the undulating uneven shape (the first and second outer surface deformation portions 10 and 11) formed by the protrusion molding is applied to the position of the bottom surface portion B1 and the position of the side wall portion B2 by press molding. At this time, in the component end surface, the flange in the vertical direction (joining end portion B3) is provided at both ends of the steel sheet which becomes the upper surface in the second molding step.

In the second molding step, the undulating uneven surface of the bottom surface portion B1 formed in the first molding step is formed by the punch 3 and the mold 5 having the curved surface having the final shape, and the spacer 4 and the punch 3 are used. The first out-of-plane deforming portion 10) is provided with a load of 50 tons and is sandwiched, and the undulating uneven surface is crushed to give a camber (bending along the longitudinal direction). Further, while the load of 50 tons is applied between the spacers 4-punch 3, the mold 5 is pressed into the mold 5, and the uneven surface portion of the side surface portion of the panel is crushed by the contact surface between the side surface of the mold 5 and the side surface of the punch 3 ( The second out-of-plane deforming portion 11) raises the side wall portion B2. When the side wall portion B2 is raised, the portion which becomes the upper surface when viewed from the side passes through the slit provided in the punch 3, and the closed section is completed. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, it is joined by laser welding.

(Second example)

This second example employs press forming as shown in (a) to (c) of Fig. 6 .

In the first molding step, the embossed uneven shape formed by the protrusion molding is applied to the position of the bottom surface portion B1 of the workpiece B and the position of the side wall portion B2 by press molding (the first and second outer surface deformation portions 10 and 11). ). At this time, in the component end surface, the flange of the vertical direction is provided at both ends of the steel sheet which is the upper surface in the second molding step, and the flange is provided along the width direction of the component.

In the second molding step, the undulating uneven surface of the panel bottom surface portion B1 formed in the first molding step is formed by the punch 3 and the mold 5 having the curved surface having the final shape, and the spacer 4 and the punch 3 are used. (the first outer surface deformation portion 10) is provided with a load of 50 tons, and is sandwiched, and the undulating uneven surface is crushed and imparted thereto. Curved surface. Further, while applying a load of 50 tons between the spacers 4-punch 3, the mold 5 is pressed into the mold 5, and the uneven surface portion of the side surface portion of the panel is crushed by the contact surface between the side surface of the mold 5 and the side surface of the punch 3. The 2 out-of-plane deforming portion 11) raises the side wall portion B2.

At this time, when the side wall portion B2 is raised, the portion which becomes the upper surface when viewed from the side is passed through the slit provided in the punch 3, and the flange portion is butted to complete the closing. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, the flange portion is joined by spot welding.

(Comparative Example 1)

In Comparative Example 1, press molding shown in (a) to (c) of Fig. 11 was employed.

In the first molding step, unlike the first example and the second example, the undulating concavo-convex shape (the first and second outer deformations) formed by the protrusion molding is not provided at the position of the bottom surface portion B1 and the position of the side wall portion B2. In the parts 10 and 11), the flanges in the vertical direction are provided at both ends of the upper surface of the steel sheet which is the upper surface in the second molding step in the second molding step.

In the second forming step, the punch 3 and the die 5 having the curved surface having the final shape are used, and the load of 50 tons is applied to the panel bottom surface portion B1 formed in the first molding step by the spacer 4 and the punch 3, and When sandwiched, the side wall portion B2 is raised by being pressed into the mold 5. When the side wall portion B2 stands up, the portion which becomes the upper surface when viewed from the side is passed through the slit provided in the punch 3, thereby completing the closing section. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, it is joined by laser welding.

"assessment"

When the closed-sectional structure having a curved shape that is curved in the longitudinal direction is processed by press forming, in the first example and the second example of the present embodiment, the pair of welded end portions can be accurately combined. . On the other hand, in Comparative Example 1, since the butting of the pair of welded end portions largely differs, it is necessary to separately shape the abutting faces of the pair of welded end portions.

As described above, according to the present embodiment, the number of steps and the number of molds can be reduced as compared with the comparative example.

Further, according to the example of the present embodiment, the appearance shape after molding can be formed without breaking or wrinkling in any of the examples. On the other hand, in Comparative Example 1, wrinkles were generated.

[Example 2]

Next, an example based on the second embodiment will be described.

Conditions for the applicable materials, welding, and the like were set to the same conditions as in the above-described Example 1, and the following three examples were used to manufacture the closed-section structural parts.

(third example)

This third example employs press forming as shown in (a) to (d) of Fig. 7 .

In the first molding step, the undulating uneven shape (the first and second outer surface deformation portions 10 and 11) formed by the protrusion molding is applied to the position of the bottom surface portion B1 and the position of the side wall portion B2 by press molding. At this time, in the end surface of the component, in the second molding step, the flanges in the vertical direction are provided at both ends of the steel sheet which becomes the upper surface when viewed from the side.

In the partition wall setting step, the formed partition wall 16 is set to the previously formed first forming step for the mold set assembled at a fixed position in the mold 5. The formed part is aligned with the partition wall providing hole and the partition wall 16 is inserted, and the insert piece 16d formed in the partition wall 16 is inserted into the partition wall installation hole opened in the bottom surface part B1. Then, the punch 3 is lowered, and the insertion piece 16d of the partition wall 16 projecting downward from the bottom surface portion B1 is bent 90 degrees toward the bottom surface portion B1 side to provide the partition wall 16.

Next, in the second molding step, the undulating unevenness of the bottom surface portion B1 formed in the first molding step is performed by the punch 3 and the die 5 having the curved surface having the final shape, and the spacer 4 and the punch 3 are used. The surface (the first outer surface deformation portion 10) was placed under a load of 50 tons, and was sandwiched, and the undulating uneven surface was crushed to give a curved surface. Further, while the load of 50 tons is applied between the spacers 4-punch 3, the mold 5 is pressed into the mold 5, and the uneven surface portion of the side surface portion of the panel is crushed by the contact surface between the side surface of the mold 5 and the side surface of the punch 3 ( The second out-of-plane deforming portion 11) raises the side wall portion B2. When the side wall portion B2 stands up, the portion which becomes the upper surface when viewed from the side is passed through the slit provided in the punch 3, thereby completing the closing section. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, it is joined by laser welding.

(fourth example)

This fourth example employs press forming as shown in (a) to (d) of Fig. 10 .

In the first molding step, the undulating uneven shape (the first and second outer surface deformation portions 10 and 11) formed by the protrusion molding is applied to the position of the bottom surface portion B1 and the position of the side wall portion B2 by press molding. At this time, in the second end step of the part, the side surface of the steel sheet which is the upper surface is provided with a flange in the vertical direction at both ends of the steel sheet, and further along the width direction of the part. Set the flange.

In the partition wall setting step, the formed partition wall 16 and the parts formed in the previous first forming step are set to the mold set set at the fixed position in the mold 5, and the partition wall providing hole and the partition wall 16 are provided. The positional alignment is such that the insertion piece 16d provided in the partition wall 16 is inserted into the partition wall providing hole opened in the bottom surface portion B1. Then, the punch 3 is lowered, and the insertion piece 16d of the partition wall 16 projecting downward from the bottom surface portion B1 is bent 90 degrees toward the bottom surface portion B1 side to provide the partition wall 16.

In the second molding step, the undulating uneven surface of the bottom surface portion B1 formed in the first molding step is formed by the punch 3 and the mold 5 having the curved surface having the final shape, and the spacer 4 and the punch 3 are used. The first out-of-plane deforming portion 10) is provided with a load of 50 tons, and is sandwiched, and crushes the undulating uneven surface to impart a curved surface. Further, while the load of 50 tons is applied between the spacers 4-punch 3, the mold 5 is pressed into the mold 5, and the uneven surface portion of the side surface portion of the panel is crushed by the contact surface between the side surface of the mold 5 and the side surface of the punch 3 ( The second out-of-plane deforming portion 11) raises the side wall portion B2. When the side wall is raised, the portion which becomes the upper surface when viewed from the side is passed through the slit provided in the punch 3, and the flange portion is butted to complete the closing. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, the flange portion is joined by spot welding.

(Comparative Example 2)

In Comparative Example 2, press forming as shown in (a) to (c) of Fig. 12 was employed.

In the first molding step, unlike the third example and the fourth example, the position of the bottom surface portion B1 and the position of the side wall portion B2 are not provided by the protrusion molding. The undulating concavo-convex shape (the first and second out-of-plane deforming portions 10 and 11) formed in the component end surface is a vertical flange provided at both ends of the steel sheet which becomes the upper surface in the second molding step. .

In the partition wall setting step, the formed partition wall 16 and the parts formed in the previous first forming step are set to the mold set set at the fixed position in the mold 5, and the partition wall providing hole and the partition wall 16 are provided. The positional alignment is such that the insertion piece 16d provided in the partition wall 16 is inserted into the partition wall providing hole opened in the bottom surface portion B1. Then, the punch 3 is lowered, and the insertion piece 16d of the partition wall 16 projecting downward from the bottom surface portion B1 is bent 90 degrees toward the bottom surface portion B1 side to provide the partition wall 16.

In the second molding step, the punch 3 and the die 5 having the curved surface having the final shape are used, and the bottom portion B1 formed in the first molding step is given a load of 50 tons by the spacer 4 and the punch 3, and is clamped. When it is pushed in, it is pressed into the die 5 to raise the side wall portion B2. When the side wall portion B2 is raised, the portion which becomes the upper surface when viewed from the side passes through the slit provided in the punch 3, thereby completing the closing section. To pull out the punch 3, a removal mechanism is provided on the side of the punch 3, and the product is pulled out in the longitudinal direction of the part. Then, it is joined by laser welding.

"assessment"

When the closed-sectional structure having a curved shape that is curved in the longitudinal direction is processed by press forming, in the third and fourth examples of the present embodiment, the pair of welded end portions can be accurately combined. . On the other hand, in Comparative Example 2, since the butting of the pair of welded end portions largely differs, it is necessary to separately shape the abutting faces of the pair of welded end portions.

As described above, according to the present embodiment, the number of steps and the number of molds can be reduced as compared with the comparative example.

Further, according to the example of the present embodiment, the appearance shape after molding can be formed without breaking or wrinkling in any of the examples.

On the other hand, in Comparative Example 2, wrinkles were generated.

1‧‧‧下模

1a‧‧‧Bottom forming part

1b‧‧‧ sidewall forming section

1c‧‧ ‧ standing up

2‧‧‧上模

3‧‧‧ Punch

3a‧‧‧ lower end

4‧‧‧shims

4a‧‧‧ upper surface

5‧‧‧

5a‧‧‧Mold side

10‧‧‧1st out-of-plane deformation

11‧‧‧2nd out-of-plane deformation

15‧‧‧ partition wall setting hole

16‧‧‧ partition wall

16a‧‧‧立起部

16b, 16c‧‧‧ side section

16d‧‧‧ inserts

17‧‧‧Sloping surface

B‧‧‧Processing materials

B1‧‧‧ bottom part

B2‧‧‧ Sidewall

B3‧‧‧ joint end (welding end)

B4‧‧‧Flexing Department

B5‧‧‧ joint surface

(a) to (b) of FIG. 1 are views showing a pressed part of a closed-sectional structure formed by press molding according to the first embodiment of the present invention, and (a) of FIG. 1 is a side view, and FIG. (b) is a perspective view.

(a) to (c) of FIG. 2 are views for explaining a mold used in the first molding step according to the first embodiment of the present invention and press molding.

(a) to (c) of FIG. 3 are views for explaining a mold used in the second molding step according to the first embodiment of the present invention and a bending press molding.

FIG. 4 is a side view showing a mold used in the second molding step according to the first embodiment of the present invention.

(a) to (c) of Fig. 5 are views showing molding of a processed material according to the first embodiment of the present invention.

(a) to (c) of Fig. 6 are views showing a modification of the first embodiment of the present invention.

(a) to (d) of Fig. 7 are views for explaining press forming according to the second embodiment of the present invention.

8 is a perspective view showing a structural example of a partition wall.

Fig. 9 is a schematic view showing the bending of the insertion piece.

(a) to (d) of Fig. 10 show a second embodiment based on the present invention. A diagram of a variation of the state.

(a)-(c) of FIG. 11 is a figure explaining the shaping|molding of a comparative example.

(a)-(c) of FIG. 12 is a figure explaining the shaping|molding of a comparative example.

10‧‧‧1st out-of-plane deformation

11‧‧‧2nd out-of-plane deformation

B‧‧‧Processing materials

B1‧‧‧ bottom part

B2‧‧‧ Sidewall

B3‧‧‧ joint end (welding end)

B4‧‧‧Flexing Department

Claims (6)

A method for producing a closed-section structural member, wherein a flat-shaped processed material is formed into a closed-sectional structure in which a bottom surface portion is curved in a longitudinal direction, and includes a first forming step of at least a bottom surface portion of the processed material. a plurality of first outer surface deformation portions each including a concave shape or a convex shape are formed along the longitudinal direction to form a plurality of curved portions, and a second forming step of sandwiching the bottom surface of the processed material by a spacer and a punch In the state of the portion position, the punch is pressed between the dies, whereby the first outer surface deformed portion is crushed by the spacer and the punch, and the bent portion is bent and formed. The method for producing a closed-section structural member according to the first aspect of the invention, wherein the flat-shaped processed material is formed into a closed-sectional structure, and the closed-sectional structure includes the bottom surface portion, a pair of left and right side wall portions on the left and right sides of the bottom surface portion, and a pair of joint end portions respectively connected to the left and right side wall portions, wherein in the first molding step, the side wall portion positions include concave shapes a plurality of second outer surface deformation portions of the convex shape and the first outer surface deformation portion are formed along the longitudinal direction, and the bending portion is formed at a boundary portion between the bottom surface portion and the side wall portion; In the second molding step, the second outer surface deformation portion is crushed by the punch side surface and the mold side surface. A method of manufacturing a closed-section structural part according to the first or second aspect of the invention, wherein After the end of the first molding step and before the bending portion is formed by the second molding step, a partition wall is provided on the bottom surface portion of the processed material. A manufacturing apparatus for a closed-section structural member, which is formed by molding a flat-shaped processed material into a closed-sectional structure in which a bottom surface portion is curved in a longitudinal direction, and includes a mold for pressing, including an upper mold and a lower mold, wherein the upper mold and the lower mold form a plurality of first outer surface deformation portions each including a concave shape or a convex shape at a position of at least the bottom surface portion of the processed material, and form a plurality of curved portions; And a gasket and a punch for clamping the bottom surface portion of the processed material to crush the first surface outer deformation portion; and a mold for sandwiching the bottom surface portion of the processing material by the gasket and the punch In the state, the above-mentioned bent portion is bent and formed by press-fitting the punch. The apparatus for manufacturing a closed-section structural part according to the fourth aspect of the invention, wherein the flat-shaped processed material is formed into a closed-sectional structure, and the closed-surface structure includes the bottom surface portion, a pair of left and right side wall portions on the left and right sides of the bottom surface portion, and a pair of joint end portions respectively connected to the left and right side wall portions, wherein the upper mold and the lower mold are configured such that the position of the side wall portion is The second outer surface deformation portion including the concave shape or the convex shape is formed in plurality along the longitudinal direction together with the first outer surface deformation portion, and the bending portion is formed at the boundary portion between the bottom surface portion and the side wall portion. Further, the second surface is externally changed by using the side surface of the punch and the side surface of the die The shape is crushed. The apparatus for manufacturing a closed-section structural part according to the fourth or fifth aspect of the invention, wherein the bending portion is formed by bending the bottom surface portion of the processed material by a gasket and a punch, A partition wall is provided on the bottom surface of the processed material.