1. Field of the Invention
The invention relates to a forming method in which a material of a workpiece is formed by means of at least one forming tool, wherein a lubricant is used between the material and the at least one forming tool. The invention also relates to a lubricant to be used in such a method and an apparatus for carrying out such a method.
2. Background Information
Such a method and a forming apparatus used for carrying out the same are known from Theo Mang's book “Die Schmierung in der Metallbearbeitung” (“Lubrication in metal working”), ISBN 3-8023-0682. It is thus known to use lubricants in metal forming methods, such as deep drawing metal sheets. By these means, the coefficient of friction between the at least one forming tool and the material is varied to influence the forming method and its result.
It is the object of the present invention to improve a forming method of the initially mentioned type in such a way that a greater variety of shapes is achievable with improved quality.
This object is achieved by a forming method according to a first aspect of the present invention.
A lubricant able to be used in such a forming method, and an apparatus for carrying out such a forming method are the subject matter of the other aspects of the present invention.
Advantageous embodiments of the invention are the subject matter of still other aspects of the present invention.
In a forming method according to the present invention, a material of a workpiece is formed by means of at least one forming tool. For this purpose, a lubricant is introduced between the material and the at least one forming tool having a viscosity which is modifiable by applying or varying a field.
The lubricant has electro-rheological and/or magneto-rheological properties, i.e., its viscosity is modified, for example, by the application of an electric or magnetic field.
In a preferred embodiment, the forming method is a metal forming method, wherein the material is a metal. The invention is particularly suitable for cold forming methods in which the metal is formed without the additional application of heat.
A magneto-rheological fluid (MRF) is particularly preferred as a lubricant.
Magneto-rheological fluids are known, for example, from “Magnetorheological fluids for adaptive engine mounts”, Fraunhofer ISC Annual Report 2004, p. 24, for the application in adaptive engine mounts for vibration damping of engine vibrations in vehicles. The present invention refers to a totally different technical field, namely to a forming method.
The forming method according to the present invention, in a preferred embodiment, is a metal sheet forming method. For example, the lubricant having a viscosity able to be influenced by a field is used in a forming method. A method is particularly preferred in which there are locally strongly varying requirements as to the coefficient of friction, such as an incremental sheet forming (ISF) process. Incremental sheet forming processes which can be further developed according to the present invention are described in the publications “3 D-Bearbeiten: Flexibles Umformen von Feinblech ohne Gegenform” (“3D-working: flexible forming of sheets without counter mold”); Fraunhofer-Institut für Produktionstechnik and Automatisierung-Robotersysteme; R+R 05.04/10.05, October 2005, and in the publication “Hämmern ins Bodenlose” (“Hammering into the void”) in “Interaktiv-Fraunhofer IPA”, No. 1.2004, pp. 14 and 15, and in DE 102 31 430 A1, DE 103 17 880 B3 and DE 10 2005 024 378 A1. Herein a forming tool is traversed along a predetermined path across the workpiece to be worked so that sections of the workpiece are incrementally formed until its ultimate shape is reached.
The properties of the variable viscosity can also be used, for example, to remove the lubricant after the forming process more easily, wherein the viscosity is modified by applying or varying a field to be able to remove the lubricant more easily after the forming process.
However, particular advantages result from the application of a lubricant with a viscosity able to be influenced by a field during the forming process. In metal forming, and in particular in incremental forming processes, it is often desirable to locally influence the coefficient of friction to optimize the process. In an advantageous embodiment of the invention, by varying the viscosity of the lubricant, the coefficient of friction between the workpiece and the forming tool can be selectively, and in particular, also locally varied. Therefore, a particularly preferred embodiment of the invention is characterized by applying to the lubricant, and/or varying on the lubricant, an electric or magnetic field influencing the viscosity of the lubricant for influencing the forming process.
By applying a field, such as a magnetic field, in the use of a magneto-rheological fluid, the viscosity of the fluid used can be varied due to the stiffness able to be influenced by the field. The field can be a single field, such as a locally differentiated field, or a plurality of locally defined and/or overlapping fields can be used. The field, or one of a plurality of fields, can be generated externally to the at least one forming tool. As a result, the geometry of the forming tool is not a limiting factor. For example, superconducting magnets can also be used for particularly strong magnetic fields.
On the other hand, with externally generated fields, it may be difficult to transfer the field strength and field orientation to the forming tool in a suitable manner. For example, both electric and magnetic fields are influenced by forming tools of metal or other metal parts of a forming apparatus. In an advantageous embodiment of the invention, it is thus provided that the or at least one of a plurality of fields is generated in or on the forming tools. An external field can also be overlapped with a field generated on the fording tools. It goes without saying that other approaches and combinations are also conceivable. Fields variable in time and/or place are also conceivable.
In an advantageous embodiment, the at least one field is conducted to the lubricant through the at least one forming tool and/or the material. This is advantageous, in particular, with forming tools of metal or with metals to be shaped, since the electric or magnetic properties of the metal materials are suitable for conducting.
For the selective process control it is preferred if different fields and/or different field strengths and/or field orientations are applied in different places and/or at different times.
The spatial distribution and/or the flux density of the field can be controlled by the shape of the at least one forming tool.
The lubricant according to the present invention for use in a forming method for forming a workpiece by means of at least one forming tool is distinguished in that it is a fluid having a viscosity variable by applying a field. By these means the viscosity can be selectively and controllably adjusted during, prior to or after the forming process by applying or varying a field, for example, to locally modify and/or adjust the coefficient of friction in the forming process and/or to facilitate the application, distribution or removal of the lubricant on or from the material or forming tool.
The lubricant is preferably an electro-rheological and/or magneto-rheological fluid which contains polarizable particles dispersed in a carrier fluid. By suitably choosing the carrier fluid and the particles, the properties of the lubricant can be adjusted. For example, the range of viscosity to be adjusted can be chosen by selecting carrier fluids of higher or lower viscosity and by selecting the particle size or particle shape. The carrier fluid is, for example, a forming oil suitable for use in a metal forming process, wherein particles polarizable by the corresponding field are dispersed. In particular, oils or other lubricants are used as a base which have lower viscosity in comparison with forming oils hitherto used in conventional metal forming methods.
The apparatus according to the present invention for forming a material of a workpiece with at least one forming tool using a lubricant is distinguished by a field generating means for generating a field influencing the viscosity of an electro-rheological and/or magneto-rheological lubricant. In the preferred use of a magneto-rheological fluid—referred to as a MRF in the following—for forming metals, the apparatus preferably has a magnetic field generating means for generating a magnetic field with which the viscosity of the MRF can be adjusted.
The apparatus is preferably configured as a metal sheet forming apparatus for cold forming of metal sheets, wherein forming tools are provided in a similar manner to well-known corresponding metal sheet forming tools. For example, a deep-drawing apparatus or IBU apparatus is provided configured for forming a metal sheet. However, any other cold forming process and at least some warm forming processes can also take advantage of the use of the present invention. The present invention can thus also be used according to other embodiments for extrusion methods and extrusion apparatuses, wire drawing methods and wire drawing apparatuses, rolling or pressing methods and apparatuses and/or to forging processes and apparatuses, such as tumble forging.
In contrast to well-known corresponding metal working apparatuses, in a preferred embodiment of the invention, the at least one forming tool has at least one permanent magnet or electric magnet.
By incorporating electronic magnets in the forming tool, a field can be designed, created and/or generated which leads to an optimum contacting state between the tool and the workpiece on any predetermined point in the contact zone.
Advantages of the invention and/or its advantageous embodiments are, in particular:
An embodiment of the invention will described in more detail in the following with reference to the accompanying drawings, in which:
In the Stribeck diagram, various film thicknesses d of a lubricant 18 and the coefficient of friction μ is indicated as a function of the factor η v/p, wherein η is the viscosity of lubricant 18, v is the relative velocity of the partners in friction 12, 14 and p is the normal pressure in contact zone 16.
A first area A characterizes a forming behavior without lubricant 18. Pure dry friction is present. The coefficient of friction μ is at a maximum μ=μmax. In a second area B, boundary layers 20 of the two partners in friction 12, 14 are wetted with lubricant 18. Lubricant 18, sparsely applied, initially deposits and adheres on the frictional surfaces. Boundary friction occurs, wherein frictional surfaces rub against each other with the adhesion of lubricant. The coefficient of friction μ is slightly lower, μ1≦μ<μmax, wherein μ1 is a coefficient of friction at the boundary between boundary friction and mixed friction. In a third area C, lubricant 18 is in spaces 21 between partners in friction 12, 14, wherein there are still more or fewer contact areas 22, in which the boundary layers 20 are still in contact. The coefficient of friction μ is lower still, μ2≦μ<μ1, wherein μ2 is the coefficient of friction at the boundary between mixed friction and purely hydro-dynamic friction. In a fourth area D, the film thickness d is sufficient to eliminate any contact areas 22. Lubricant 18 is everywhere between the boundary layers 20. Purely hydro-dynamic friction is present.
The coefficient of friction μ can be optimized in area C of mixed friction and, in particular, in area D of purely hydro-dynamic friction by viscosity control. Viscosity can also be used to adjust thrust tension τ in contact zone 16, wherein τ=ηdv/dt, wherein dv/dt is the derivative of v with respect to time.
In metal forming and, in particular, in incremental forming processes, it is desirable for optimizing the process to locally influence the coefficient of friction to selectively influence the forming method at a particular place. This can be done, as explained above, by influencing the viscosity of a lubricant 18 used in metal forming. To this end, in the forming methods explained in more detail in the following, a fluid is used which has a viscosity variable by applying or varying a field. In the exemplary embodiments, this is a magneto-rheological fluid, referred to as MRF in short in the following.
An MRF is an intelligent liquid material, the rheological properties of which can be sensibly, mostly drastically, controlled, reversibly in most cases, by a magnetic field. An MRF becomes gel-like in a magnetic field, for example, and reverts to the liquid state after switching off the magnetic field. MRFs are analogous to electro-rheological fluids—ERF—which are usable in an alternative embodiment, where it is possible, due to the materials, to effectively apply an electric field. An MRF is produced by a dispersion of magnetically polarizable particles in a carrier fluid.
A first exemplary embodiment will be explained in more detail in the following with reference to the illustration in
It is shown in
In
By using a magneto-rheological fluid—MRF—60, the viscosity η of forming oil 54 is adjusted as required in each situation by a magnetic field 56 to improve the forming process.
In the forming method presented here, magnetic field 56 is generated externally via magnetic field generating means (not shown) comprising, for example superconducting magnets, and/or in forming tools 14, 44, 48, 50 and conducted through the working surfaces of forming tools 14, 44, 48, 50 and through metal sheet 30.
For this purpose, forming tools 14, 44, 48, 50 have electronic magnets 58, for example, electronically controllable electric magnets. Magnetic field 56 can vary the stiffness of MRF 60. Due to the shape of the corresponding forming tool 14, 44, 48, 50, the spatial distribution and the magnetic flux density of magnetic field 56 can be predetermined.
Magnetic field 56 is adjusted by a control (not shown in any more detail) in such a manner that a viscosity variable over time, and therefore a coefficient of friction μ62 variable over time, is adjusted on clamping surfaces 62 of jaws 48, 50, to hold tight the edge of metal sheet 30 or to enable additional material to flow depending on the forming progress. The magnetic field, and therefore the viscosity of MRF 60, is adjusted at the contact surfaces 64 by the control in such a way that a relatively low coefficient of friction μ64 is present at the contact surface 64. At the edge areas 44 of punch 42, magnetic field 56 is adjusted in such a way that a viscosity of MRF 60 is adjusted which leads to a high coefficient of friction μ44.
MRF 60 is adapted by its composition to a desirably adjustable range of viscosity. For this purpose, the size distribution of the magnetizable particles in MRF 60 and the carrier fluid are optimized. Forming oil 54 is used as the carrier fluid, wherein a particularly low-viscosity forming oil 54 is chosen for this task.
Although the forming method has been described with reference to an example of a sheet drawing method, the application of a fluid having a viscosity controllable by a field is not limited to such sheet drawing methods but can be applied also to other metal working methods. It can be transferred to corresponding forming methods for forming other materials by means of forming tools which can be influenced by different viscosities of the lubricants or separating agents used.
Particular advantages are offered by the application of a fluid with a viscosity controllable by a field in an incremental forming method, in particular in an incremental sheet forming (ISF) method, as described and claimed, for example, in the publications “3 D-Bearbeiten: Flexibles Umformen von Feinblech ohne Gegenform” (“3D-working: flexible forming of sheets without counter mold”); Fraunhofer-Institut für Produktionstechnik and Automatisierung-Robotersysteme; R+R 05.04/10.05, October 2005, and in the publication “Hämmern ins Bodenlose” (“Hammering into the void”) in “Interaktiv-Fraunhofer IPA”, No. 1.2004, pp. 14 and 15, and in DE 102 31 430 A1, DE 103 17 880 B3 or DE 10 2005 024 378 A1.
As shown in more detail in
Different compression strengths p1, p2, p3 can thus be generated, for example, in different areas of contact surface 64 between forming tool 142 and metal sheet 30, as shown in
Although the use of a magneto-rheological fluid has been described in the above-mentioned exemplary embodiments, the invention is not limited to the use of magneto-rheological fluids. An electro-rheological fluid could also be used, for example, having a viscosity variable by applying an electric field. To this end, a forming tool 14, 44, 48, 50, 142 of the exemplary embodiments described could be configured, for example, as an electrode for applying an electric field.
Number | Date | Country | Kind |
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10 2007 026 592 | Jun 2007 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2008/056948 | 6/4/2008 | WO | 00 | 2/7/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/148826 | 12/11/2008 | WO | A |
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3756051 | Rebsamen et al. | Sep 1973 | A |
5480573 | Durfee et al. | Jan 1996 | A |
6106380 | Jacobs et al. | Aug 2000 | A |
6503414 | Kordonsky et al. | Jan 2003 | B1 |
20040148997 | Amino et al. | Aug 2004 | A1 |
Number | Date | Country |
---|---|---|
693 11 241 | Jan 1998 | DE |
101 35 488 | Apr 2003 | DE |
102 31 430 | Feb 2004 | DE |
102 48 329 | Apr 2004 | DE |
103 17 880 | Oct 2004 | DE |
10 2004 055 415 | May 2006 | DE |
10 2005 024 378 | Nov 2006 | DE |
0 317 186 | May 1989 | EP |
0 317 186 | May 1989 | EP |
1-293925 | Nov 1989 | JP |
Entry |
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Theo Mang, “Die Schmierung in der Metallbearbeitung” (“Lubrication in metal working”), book, 1983, pp. 243-256, ISBN 3-8023-0682-1, Vogel-Buchverlag, Germany. |
“Magnetorheological fluids for adaptive engine mounts”, Fraunhofer ISC Annual Report 2004, p. 34-35; Fraunhofer ISC, Germany. |
“3 D-Bearbeiten: Flexibles Umformen von Feinblech ohne Gegenform”, Fraunhofer-Institut für Produktionstechnik and Automatisierung—Robotersysteme; R+R 05.04/10.05, Oct. 2005, Germany. |
“Hämmern ins Bodenlose”, Interaktiv—Fraunhofer IPA, No. 1.2004, pp. 14-15, Germany. |
Number | Date | Country | |
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20110113845 A1 | May 2011 | US |