The present invention relates to a forming tool for forming sheet blanks in a diaphragm press of the kind comprising an openable, closed pressure chamber, which is divided in a gas and liquid tight manner by means of a flexible diaphragm, the forming tool being adapted to be arranged on one side of the diaphragm and a sheet blank to be formed being adapted to be arranged between the forming tool and the diaphragm, while the opposite side of the diaphragm is adapted to be pressurised by a fluid being supplied at high pressure to cause the flexible diaphragm to deform and, thus, the sheet blank to be pressed against the forming tool, the forming tool further comprising a cutting edge, so that the sheet blank is both formed into the desired shape and cut to the desired size in a single forming step.
In connection with forming sheet blanks, such as sheets of steel or aluminium for use in vehicles, it is known to use so-called diaphragm presses of the kind described above. In such a press, a forming tool is provided in a closed press chamber and the sheet blank to be formed is arranged between the forming tool and an elastic diaphragm of rubber or a polymer, which divides the press chamber in two separate chamber portions in a gas and liquid tight manner. By supplying a liquid at high pressure at the opposite side of the diaphragm, the diaphragm will be deformed and press the sheet blank against the forming tool whereby the blank obtains the desired shape. Forming using diaphragm presses of this kind is particularly advantageous in conjunction with relatively small production runs, since the cost of manufacturing the forming tools is relatively low.
However, in forming operations using a diaphragm press, as in every other kind of forming operation, it is desirable that, to the utmost possible extent, the blank be formed into a finished product in one single forming step, thereby avoiding, as far as possible, any subsequent machining that would increase the costs. Thus, it is desirable that, in the forming operation, the blank be cut to the correct size and shape and that, if desired, flanged edges be formed, said flanged edges being used, for example, for attaching the finished blank and for connecting it to other structural elements of the end product, such as a vehicle.
EP 0 288 705 discloses a forming tool for diaphragm presses by means of which it is possible to cut the sheet-metal blank to the desired size and to form a flanged edge along the periphery of the cut sheet-metal blank. This is achieved by the forming tool having cutting bars with a sharp cutting edge along the circumference of the forming tool and recesses for forming the flanged edges after cutting. During the forming process, the sheet-metal blank will, at a certain degree of deformation, be pressed against the cutting edges, which will cause the sheet to rupture and be cut off to the predetermined size, flanged edges being then formed at the cut-off edge portions by said portions being pressed into the recesses provided therefor in the forming tool. One drawback of this forming tool is, however, that the sheet-metal blank has to be deformed over a very long distance before it reaches the cutting edge and is cut off, which has a negative effect on the dimensional accuracy and other quality aspects. In addition, it is often desirable to prestretch the sheet-metal blank in one direction to the yield point of the material, preferably 3–6% beyond the yield point, before the forming operation in order to avoid elastic springback of the sheet-metal blank after forming. This implies a lateral contraction of the sheet-metal blank in the other direction, and in the case where there are large recesses, for example for the purpose of forming flanged edges, parallel to the stretching direction, the sheet-metal blank will be deformed by said recesses, which results in a product of inferior quality.
The present invention aims at providing an improved forming tool for diaphragm presses, which allows the sheet blank to be cut to the desired size and a flanged edge to be formed by bending along at least part of the periphery of the sheet-shaped blank and/or along a circumferential edge of an opening therein in a single forming step, while ensuring a high degree of dimensional accuracy and shape permanence as well as a finished product of high quality. An additional advantage obtained by means of the forming tool according to the invention is that it is easier to remove both the formed product and the remaining surplus or scrap after the forming operation. At least said objects and advantages are obtained by means of a forming tool according to claim 1.
The invention is thus based on the understanding that the above objects and advantages are obtained if the forming tool, in the places where the sheet blank is to be cut and bent to form a flanged edge, is provided with an elongate cutting and flanging tool, which is displaceable with the aid of actuating means towards and away from the diaphragm in a slot in the forming tool. In one typical embodiment, the forming tool can comprise, as shown and described also in connection with the following working examples, such a cutting and flanging tool for the purpose of cutting the sheet-metal blank and bending it to form a flanged edge along the whole periphery of the blank. One example of such an application is car body panels in the form of, for example, a car hood or a car roof. However, a cutting and flanging tool could also be adapted to cut the blank and bend it to form a flanged edge along the circumference of an opening therein, for example for the purpose of forming window and ventilation openings in car body panels. It would also be conceivable to form a flanged edge by cutting and bending along only part of a body panel edge or a circumferential edge of an opening in the blank. In such cases, the cutting and flanging tool does not need to extend continuously in a closed loop, but may be arranged along a limited section having a beginning and an end.
Preferably, the cutting and flanging tool is, in an initial position, flush with the forming surface. The cutting function is achieved by the cutting and flanging tool being provided with a sharp shoulder edge, which serves as a cutting edge and which, conveniently, can have a height 1–3 times the thickness of the sheet blank to be formed. When a sufficiently high pressing pressure has been reached, the blank is cut along said edge, the cutting thus being effected before the blank has been deformed to a significant degree. Owing to the small depth of the recess, its negative influence on the blank, perpendicularly to the lateral contraction, in connection with any prestretching will be insignificant. Moreover, by arranging the cutting edge on the cutting and flanging tool, it is easy to provide a flanged edge of varying width by forming the cutting edge at different distances from the edge of the cutting and flanging tool that is oriented towards the forming surface of the forming tool against which the blank is formed.
The cutting and flanging tool is moved towards and away form the diaphragm with the aid of an arbitrary type of actuating means. In the preferred embodiment, the actuating means is formed of a plurality of hydraulically operated pistons arranged at intervals of about 100 mm. However, other types of actuating means are also conceivable. At low pressures, pneumatic pistons could be used, for instance.
In the preferred embodiment, the inward displacement of the cutting and flanging tool is controlled by the pressing pressure being exerted, by way of the diaphragm, on a release valve, which, when the pressure is high enough, is pressed inwards and actuates a valve body, which drains the hydraulic system of the pistons, thus allowing the cutting and flanging tool to be forced inwards by the pressing pressure exerted thereon. In this way, the diaphragm will press the edge portion of the cut blank into the slot in the cutting and flanging tool, so that said edge portion will form an inwardly bent flanged edge. After a possible further pressure increase aiming at a final forming of the blank, the pressure in the pressure chamber is released and the press can then be opened. By the position of the cutting and flanging tool in the slot being controllable with the aid of one or more actuating means, both the finished product and the cut-off scrap can be easily disengaged from the forming tool by the actuating means being caused to displace the cutting and flanging tool outwards. The cutting and flanging tool will thus disengage the finished product and the scrap and press them out of the forming tool. In many cases, the product and the scrap will stick firmly to the forming tool.
In the following working example, one embodiment of the forming tool for forming car body panels will be described. It will be appreciated, however, that the forming tool according to the invention can also be used for forming other sheet blanks.
The drawings show, by way of example, one embodiment of the invention.
In the following, an embodiment will be described in which the forming tool is used for forming sheet-metal blanks for the automotive industry.
A forming tool 6 according to the invention having an annular cutting and flanging tool 7 is arranged in the bottom tray. Edge elements 8 with schematically illustrated stretching means 9, 9′ are provided between the forming tool 6 and the side walls of the bottom tray 2, and both the forming tool and the edge elements 8 rest on a bottom plate 10.
In connection with forming using the diaphragm press shown, a sheet-metal blank 11 to be formed is arranged between the forming tool 6 and the diaphragm 5, two opposite side edges thereof being inserted in the stretching means 9, 9′, as shown in
Reference is now made to
The figures also show the release valve 14, the outer surface of which is located slightly within the outer surface of the forming tool. The release valve 14 is spring-loaded towards the exterior by means of cup springs 19 and the innermost end of the release valve comprises a valve body 20, which is capable of closing and opening a passage in a hydraulic pipe 21.
In an initial position, as shown in
In
In
In
In the schematic cross sections 7 and 8, the function of the release valve 14 is shown in more detail. In
In
After the forming operation has been completed, when the pressure has been released from the press chamber 4 and the upper part 3 of the press as well as the diaphragm 5 have been removed, the release valve 14 will return to its initial projecting position, thus causing the passage in the hydraulic pipe 21 to close. By generating once more, at this stage, a hydraulic pressure in the pipe 24, the hydraulic cylinders 18 will cause an outward displacement of the cutting and flanging tool 7 and both the finished product and the remaining scrap will be displaced outwards and disengaged from the forming tool.
Number | Date | Country | Kind |
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0201489 | May 2002 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE03/00525 | 4/2/2003 | WO | 00 | 10/28/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO03/097268 | 11/27/2003 | WO | A |
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Number | Date | Country |
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199 51 850 | Jan 2001 | DE |
0 288 705 | Nov 1988 | EP |
940930 | Jul 1982 | SU |
Number | Date | Country | |
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20060086166 A1 | Apr 2006 | US |
Number | Date | Country | |
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60384175 | May 2002 | US |