This application is a national stage application of International Application No. PCT/JP2010/053935, filed Mar. 3, 2010, which claims priority to Japanese Patent Application No. 2009-050144, filed Mar. 4, 2009, the content of which is incorporated herein by reference.
The present invention relates to a working apparatus for shaping sheet metal and a working method using that working apparatus.
In recent years, for example, in the fields of auto parts, building material parts, furniture parts, etc., high strength sheet metal has been used for realizing lighter weight while securing rigidity. Such sheet metal has been shaped in the past by, for example, press forming or roll forming, but the drop in formability accompanying the increase in strength of the sheet metal is making it difficult to form such sheet metal into complicated shapes.
For example, when using press forming, a flange part of the shaped sheet metal upon which a tensile force acts sometimes becomes cracked at that flange part, or the flange part of the sheet metal upon which a compressive force acts sometimes becomes wrinkled at that flange part.
Further, when using roll forming, it is possible to form a sheet metal to a single simple cross-sectional shape in the longitudinal direction, but forming sheet metal into a complicated shape where the cross-section changes in the longitudinal direction is difficult.
On the other hand, it has been proposed to combine press forming and roll forming so as to shape sheet metal. For example, in PLT 1, there is provided a press apparatus for forming splines or other gearwheel shapes at the outer circumferential surface by roll forming which has a die at the outer circumferential surface of which the sheet metal to be worked is loaded, a die ring arranged concentrically with the die, and a plurality of forming rolls which are arranged radially at the inner circumference of the die ring and which rotate while being gripped between the sheet metal and the inner circumferential surface of the die ring. Further, the die ring is made to move relative to the die and the plurality of forming rolls are made to rotate so as to shape the sheet metal.
PLT 2 discloses a roll forming method in a roll forming apparatus which forms a long object like a frame part into a curved shape, wherein the forming rolls are made to move on a translation cam matching the shape of the long object and wherein the forming rolls are made to ascend or descend so as to follow the shape of the translation cam and thereby work the object into a shape curved in the longitudinal direction.
PLT 3 discloses a roll forming method which joins together perpendicularly intersecting sheet metal (seaming) during which folding back the sheet metal at the seam part (hemming) and forming the seam part at that time by placing a forming roll having a right angled cross-section against the right angle seam part of the sheet metal and rotating it while pressing.
PLT 1: Japanese Patent Publication (A) No. 6-154925
PLT 2: Japanese Patent Publication (A) No. 64-31527
PLT 3: Japanese Patent Publication (A) No. 8-197161
However, in the art described in PLT 1, while the sheet metal can be formed into a gearwheel shape (wavy shape), the cross-section in the longitudinal direction becomes the same shape. That is, it is not possible to form sheet metal into a complicated shape such as one where the cross-section changes in the longitudinal direction. Further, it is also not possible to form sheet metal so that its height changes in the longitudinal direction. Therefore, it is not possible to form sheet metal to a three-dimensionally complicated shape.
The art described in PLT 2 also can be applied to the case of working a material having a cross-section in the longitudinal direction of the same shape and furthermore curved in a direction perpendicular to the longitudinal direction, but it is not possible to form the sheet metal into a complicated shape with a cross-section which changes in the longitudinal direction.
In the art described in PLT 3 as well, it is possible to work a material to give a fixed shape at the shoulder parts, but it is not possible to form sheet metal to a complicated cross-section or a complicated shape of a changing cross-section.
Further, what these prior arts have in common, it may be said, is that they are mere extensions of the conventional roll forming method, so are not suitable for working sheet metal having a high strength such as high strength steel. A working technique which is efficient and is high in general applicability is being sought for meeting the future rising demand for working high strength sheet metal into any shapes.
The present invention was made in consideration of the problem that with the conventional roll forming technique, there are limits to the work and that forming a material so as to produce a complicated cross-section or a complicated shape of a changing cross-section is not possible and in consideration of the demand for an efficient method of working high strength sheet metal. That is, the problem to be solved by the present invention is the provision of an efficient, general use forming technique for forming high strength sheet metal into a three-dimensionally complicated shape. Here, “forming into a complicated shape” includes, for example, in a cross-sectional hat-shaped part, working it so that the width of a hat part changes, the width of a flange part changes, or an elongated flange part and a compressed flange part both exist. Of course, forming a three-dimensional complicated shape for which a desired shape of the final product is difficult to obtain by simple press forming due to the mixture of compressed parts and elongated parts is also included.
The inventors engaged in in-depth studies to solve this problem and as a result discovered that by combining press forming, which enables efficient working of high strength sheet metal, and roll forming, which is suitable for working complicated shapes, and pressing a roll against a press die to work the sheet metal, even high strength sheet metal can be optimally worked to any shape and thereby completed the present invention.
That is, the present invention provides a working apparatus for shaping sheet metal comprising a die (also called a “punch”) which has a shape suitable for a shape of the shaped sheet metal, a plurality of rolls which grip sheet metal with the die to shape the sheet metal, roll movement mechanisms which make the rolls independently move in a horizontal direction and make them independently ascend or descend in a vertical direction, and a roll angle setting mechanism which can change an angle by which the rolls are pressed against the die.
According to the present invention, the rolls can be moved along the ridge lines of the die in the horizontal direction independently, so even if the cross-section of the shaped sheet metal changes in the longitudinal direction, it is possible to make the rolls move while tracking the changes in the cross-section. Further, the rolls can be made to ascend and descend in the vertical direction independently, so even if the shaped sheet metal changes in height, it is possible to make the rolls ascend and descend while tracking the changes in height and have the rolls and corresponding working surface of the die grip the sheet metal by a predetermined load. In this way, the rolls can be independently made to move three-dimensionally, so it is possible to form the sheet metal into a three-dimensionally complicated shape.
Further, it is possible to provide a roll angle setting mechanism which can adjust the angle by which the rolls are pressed against the die and to handle the operation for forming any complicated shape by joint operation with the three-dimensional movement mechanisms.
Furthermore, the rolls can be respectively given load detection devices. These load detection devices can be used to control the working load at the time of shaping so as to shape the material.
In addition, the die may also move up and down while shaping the material.
Note that, a “three-dimensionally complicated shape” includes the shape of a part with a width changed in any way.
Each of the rolls may have a main roll part and a projecting roll part which projects out concentrically from the main roll part and has a diameter smaller than the main roll part.
An outer circumferential surface of a corner part of a main roll part and a projecting roll part may be provided with, over its entirety, a curved part which is curved to project outward to an inside in a side view, and the plurality of rolls may have rolls provided with curved parts with different radii of curvature.
Note that, a “corner part” means a part formed by a surface of a main roll part and an outer circumferential surface of a projecting roll part.
The plurality of rolls may have rolls which are provided with projecting roll parts with different diameters.
The bottom surface of the die may have a shape with an inside which projects out compared with the outer sides, while the projecting roll parts may project out to the inside compared with the main roll parts. Further, the bottom surface of the die may have a shape with outer sides which project out further compared with an inside, while the projecting roll parts may project out to the outer sides compared with the main roll parts.
Another aspect of the present invention is a working method using a die and a plurality of rolls to shape sheet metal characterized in that the rolls ascend independently in a vertical direction and in that the rolls and the die grip sheet metal between them by a predetermined load while the die shapes the sheet metal.
Further, the rolls may be moved along ridge lines of the die independently.
Furthermore, the rolls may not only ascend or descend in the vertical direction, but also move in the horizontal direction and may grip and shape the sheet metal at any position by a predetermined load.
At that time, the rolls may be set by the working roll angle setting mechanism to any angle for pressing against the die for shaping the material.
It is also possible to use the plurality of rolls moving back-and-forth (reciprocal motion) horizontally along a ridge line of a bottom face of the die so as to shape the sheet metal.
Each of the rolls may have a main roll part, a projecting roll part which projects out from the main roll part and which has a smaller diameter than the main roll part, and a curved part which is provided over an entirety of an outer circumferential surface of a corner part of the main roll part and the projecting roll part and which is curved to project to an inside in a side view. It is possible to use a plurality of rolls with different radii of curvature of curved parts to shape the sheet metal.
It is also possible to use a plurality of rolls with different diameters of the projecting roll parts to shape the sheet metal.
The shaped sheet metal may have an elongated flange part and a compressed flange part.
At that time, at an elongated flange part where a tensile force acts on the shaped sheet metal, a pair of the rolls may be moved in a direction approaching each other centered about the elongated flange part to thereby shape the elongated flange part. Further, at a compressed flange part where a compressive force acts on the shaped sheet metal, a pair of the rolls may be moved in a direction separating from each other centered about the compressed flange part to thereby shape the compressed flange part.
Of course, the sheet metal may also be high strength steel which has a 780 MPa or higher tensile strength. Furthermore, among tensile strength 980 MPa or higher ultra high strength steels as well, it may be 1470 MPa or higher ultra high strength steel.
According to the present invention, it is possible to efficiently form high strength sheet metal into a three-dimensionally complicated shape.
Below, an embodiment of the present invention will be explained.
In the present embodiment, the working apparatus 1 is used to work sheet metal H so that, as shown in
The working apparatus 1, as shown in
Below the die 10, as shown in
On the rail 20, as shown in
Each of the rolls 30, as shown in
The roll movement mechanisms 40, as shown in
The cylinders 43 and drive mechanisms 44 of the roll movement mechanisms 40, as shown in
Further, the control unit 50 controls the drive mechanisms 44 to control the movement of the rolls 30 to 33 in the horizontal direction, for example, the movement directions, movement speeds, numbers of times of reciprocating motion, etc. The predetermined load when gripping the sheet metal H and the movement of the rolls 30 to 33 in the horizontal direction are set by the material, thickness, or formed shape of the sheet metal H. Note that, depending on the set conditions, reciprocating motion of the rolls 30 to 33 in the horizontal direction is not necessary—a single movement is enough to shape the sheet metal H.
Above, an aspect where the drive mechanisms move on rails 20 and 21 and therefore the rolls also respectively move independently was explained. However, with this aspect, movement is possible only in the range where the rails are arranged, but there is no need to be bound by this. Various aspects may be considered.
For example, any drive mechanisms 44 which enable movement to any position on a horizontal platen (not shown) can make the individual rolls independently move to any positions. These also enable the rolls to be moved up and down in the vertical direction through the cylinders 43 and support members 42, so as a result the rolls can also be independently arranged at any position in a three-dimensional space. In this way, the movement mechanisms are not limited to this aspect. Any ones which enable the rolls to be arranged in a three-dimensional space falls under the technical scope of the present invention.
Further, in the above aspect, the angles by which the rolls 30 are attached to the roll movement mechanisms 40 are fixed, but, for example, in
Whatever the aspect, the working load acts as a reaction force on the rails 20 and 21 or horizontal platen (not shown) or other support members of the drive mechanisms 40. The support members are simple shapes, so can be easily given rigidity for withstanding the working reaction force. By designing the rigidity of the apparatus as a whole in accordance with the metal material being worked, it is possible to easily design an apparatus able to handle even materials requiring a large working load such as high strength steel or ultra high strength steel or ultra ultra high strength steel.
Next, the method of using the working apparatus 1 configured as shown in
First, as shown in
According to the above embodiment, the rolls 30 to 33 can be moved by the drive mechanisms 44 along the ridge lines L1 and L2 of the bottom surface of the die 10 in the horizontal direction independently, so even if the cross-sectional shape of the shaped sheet metal H changes, the change in the cross-sectional shape can be tracked and the rolls 30 to 33 made to move. Further, the rolls 30 to 33 can be made to ascend/descend by the cylinders 43 in the vertical direction independently, so even if the shaped sheet metal H changes in height, it is possible to track the changes in height and make the rolls 30 to 33 ascend/descend so as to have the rolls and the bottom surface of the die grip the sheet metal between them by a predetermined load. Since the rolls 30 to 33 can be made to independently move in three dimensions in this way, the sheet metal H can be worked to a three-dimensionally complicated predetermined shape.
Further, the cylinders 43 and the drive mechanisms 44 are controlled by the control unit 50, so the bottom surface of the die 10 and the rolls 30 to 33 can grip the sheet metal H between them constantly by a predetermined load. For this reason, it is possible to form the sheet metal H precisely to a predetermined shape.
In this regard, as shown in
Further, as shown in
In the above embodiment, the rolls 30 to 33 had the same shapes, but as shown in
Further, when using the above rolls 30 to 33 to shape the sheet metal H, first, the rolls 33 having the curved part 30c with the large radius of curvature are used to shape the sheet metal H. Next, the rolls 31 and 32 are successively used to shape the sheet metal H. Finally, the rolls 33 not having a curved part are used to form the sheet metal H into a predetermined shape. In this way, it is possible to shape the sheet metal H in stages so as to efficiently form the sheet metal H into a predetermined shape.
Note that, to shape the sheet metal H in stages in the above way, it is also possible to successively reduce the diameters of the projecting roll parts 30b to 33b of the rolls 30 to 33.
In the above embodiment, a die 10 with a projecting part 11 formed at the inside of the bottom surface was used, but, as shown in
The projecting parts 61 of the die 60 are formed at the two outer sides at the bottom surface of the die 60. In this case, the rails 20 and 21 are laid along ridge lines L3 and L4 of the projecting parts 61. Further, the rolls 30 are made to match with the shapes of the projecting parts 61 by having the main roll parts 30a be arranged at the inside of the projecting part 61 and having the projecting roll parts 30b be arranged below the projecting parts 61. That is, the rolls 30 are arranged on the rails 20 and 21 so that the projecting roll parts 30b project out to the outer sides. Note that, the rolls 31 to 33 may be similarly arranged on the rails 20 and 21.
In the above embodiment, for the cylinders 43, hydraulic cylinders were used, but the invention is not limited to this so long as it is possible to control the ascent/descent of the rolls 30 to 33 in the vertical direction. For example, for the cylinders 43, electric powered cylinders or pneumatic cylinders etc. may be used. Further, for example, when the vertical load of the rolls 30 to 33 is constant, springs may be used for the cylinders 43.
Further, in the above embodiments, the drive mechanisms 44 had motors (not shown) etc. built into them, but the motors may also be provided outside of the drive mechanisms 44 to make the rolls 30 to 33 move in the horizontal direction. Furthermore, the drive mechanisms 44 of the rolls 30 to 33 may, for example, be connected by wires and the drive mechanisms 44 used to make the rolls 30 to 33 move in the horizontal direction.
Below, the formability of sheet metal when using the working apparatus of the present invention will be explained in comparison with the case of using a conventional working apparatus. In the examples, as the working apparatus for the sheet metal, the working apparatus 1 shown in
Further, these working apparatuses were used to form the three types of steel sheets having the mechanical properties shown in Table 1, that is, soft steel sheet (Test Material No. 1), 780 MPa HSS steel sheet (Test Material No. 2), 980 MPa HSS steel sheet (Test Material No. 3), and 1470 MPa steel sheet (Test Material No. 4), respectively to the shape shown in
The inventors ran experiments under the above conditions. As a result, when using the conventional working apparatus, the steel sheet of Test Material No. 1 had a good formability, but with the steel sheet of Test Material No. 2, wrinkles were formed at the compressed flange part (compressed flange part B in
As opposed to this, when using the working apparatus of the present invention, it was possible to work the steel sheets of all of the Test Material No. 1 to No. 4 well. Therefore, it was learned that when using the working apparatus of the present invention, it is possible to work high strength steel sheet into complicated shapes with a good precision.
Further, each of the steel sheets of Test Material Nos. 3 and 4 of Table 1 was worked so as to give a product as shown in
Industrial Applicability
The present invention is useful when working sheet metal into a three-dimensionally complicated shape.
Number | Date | Country | Kind |
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2009-050144 | Mar 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/053935 | 3/3/2010 | WO | 00 | 9/1/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/101295 | 9/10/2010 | WO | A |
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Entry |
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Number | Date | Country | |
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20110314886 A1 | Dec 2011 | US |