DE102012014785A1 - Method for manufacturing running gearing of planetary gear, involves displacing upper tool relative to lower tool, and choosing speed of relative displacement process such that transformation of blank is executed in partial adiabatic manner - Google Patents

Abstract

The method involves preheating a blank (7) at a temperature of 80-300 degree Celsius, and arranging the blank on a lower tool (5) i.e. mold, where the blank is made of metallic material. An upper tool (3) i.e. stamper, is displaced relative to the lower tool, and the blank is re-shaped into a component, and speed of the relative displacement process is chosen based on shaping properties of material and geometry of the component such that transformation of the blank is executed in a partial or complete adiabatic manner, where transformation speed is 102-105 m/s. An independent claim is also included for a device for manufacturing a component.

Description

The invention relates to a method for producing a component according to claim 1, a device for carrying out the method according to the preamble of claim 9 and a component according to claim 10.

Methods and devices of the type discussed here are known. From the DE 10 2007 036 708 A1 Go forth a method and an apparatus for the production of gears for positive force and motion transmission, in particular for producing a running gear teeth of planetary gears. In this case, a profiled and solid trained workpiece is formed from a metallic material with a very high impact velocity of a tool on the workpiece. Such gears, in particular planet gears, are relatively massive components with a comparatively large and relatively homogeneous cross-section. It is desirable even components with large cross-sectional or thickness differences, for example, cup-shaped components with very thin floor, and components that include corners, filigree structures or upset elements to be able to produce one-stage with high Endkonturenähe. This is hardly possible with known methods: By cold forming only simple geometries are feasible, and a mold filling is limited. During lukewarm and warm forging, only imperfect shaping, especially filigree contours, is possible. When hot forming, there is a risk of scaling of the component surface, a marginal end and a delay of the component to be formed. A precision forging, by means of which in principle the components discussed here are produced, brings an extremely high tool load, thus short life for the tools with it. Finally, the production by means of machining is associated with a large loss of material and a lower strength of the components.

The invention is therefore based on the object to provide a method, a device for one-stage production of components and a component with high Endkonturnähe, the method is particularly suitable for components with large cross-sectional or thickness differences, at the same time forces on tool components - in particular compared to precision forging - are low.

The object is achieved by providing a method with the steps of claim 1. A blank is placed in a lower tool for the component to be formed. An upper tool is displaced relative to the lower tool, and the blank is formed into the component. In this case, a speed for the relative displacement of the upper tool to the lower tool is selected so that the deformation of the blank is at least partially adiabatic. The tool speed and in particular also the forming speed are increased to the extent that at least part of the forming work is converted into heat which does not diffuse out of the workpiece on a relevant time scale of the forming process, but rather remains in the latter. This results in a temperature increase of the blank, whereby its material can flow better in the tool. So are readily one-stage and with high Endkonturnähe large cross-sectional differences can be displayed, and there are in particular corners, filigree structures and upset elements by radial and / or axial flow of material can be formed. Also gears are displayed accordingly. At the same time, the forces acting on the lower and the upper tool are comparatively small, so that they have a long service life.

It is possible that the lower tool is held stationary while only the upper tool is displaced. It is also possible that the upper tool is held, while only the lower tool is displaced. Finally, it is possible to relocate both the upper tool and the lower tool. It is only essential that a relative displacement of the upper tool relative to the lower tool is effected with a sufficient speed.

Preferably, the lower tool is designed as a die or partial negative mold for the component to be formed. Accordingly, the upper tool is preferably designed as a punch or as a complementary partial negative mold for the component to be formed. In a maximally approximate state, a space thus remains between the lower tool and the upper tool, which at least substantially corresponds to a final contour of the component to be formed. This space is filled during forming with the material of the blank, whereby the component is formed. Since the shape thus produced already essentially corresponds to the final contour, no elaborate and expensive post-processing steps are required. In particular, it is not necessary to remove material to a considerable extent from the component in order to ultimately realize its final contour.

In addition to the advantageous embodiment described here as a vertical press and a horizontal press arrangement is possible.

A method is preferred which is characterized in that the speed for the relative displacement of upper tool and lower tool is selected such that the deformation of the blank completely adiabatic runs. The forming work then remains completely as heat in the blank, making the process particularly efficient.

A method is also preferred which is characterized in that the speed is matched to the forming properties of a material comprising the blank or of which the blank is made. It turns out that not only the forming properties, but also the conversion of at least part of the forming work into heat depends on material-specific parameters. Accordingly, both the speed for the relative displacement of the upper and lower tool to each other and a realized in the blank forming speed are material-dependent. For each material it is possible to find an optimal speed and to select accordingly for the process.

A method is also preferred which is characterized in that the speed is selected depending on the material and a component geometry to be formed. Accordingly, not only the material is considered, but the geometry of the component to be ultimately formed is included in the consideration. Depending on the material, it may be advantageous to adapt the speed to the actual conditions.

A method is also preferred which is characterized in that a forming speed of at least 10 ² s ^-1 to at most 10 ⁵ s ^{-1 is} selected. The forming speed is defined as the derivation of the degree of deformation over time. Preferably, a forming speed is selected in which the material of the blank has optimum forming properties, which lead to a homogeneous deformation and thus to homogeneous component properties. The optimal forming speed depends on the material and the component geometry. Ultimately, the speed for the relative displacement of the upper and the lower tool to each other is chosen so that an optimal forming speed adapted to the specific conditions, in particular the material and the component geometry is achieved.

A method is also preferred which is characterized in that the blank is preheated. This makes it possible to reduce the value for the forming speed and thus also for the tool speed. Preferably, the blank is preheated to a temperature of at least 80 ° C to at most 300 ° C. In this case, depending on the material of the blank, the optimum forming or tool speed decreases by, for example, twenty times in comparison to the values valid for a blank present at room temperature. It is thus possible to realize a high flow and shape filling capacity of the material at the same time significantly reduced forces on the tool and thus again increased service life for the tool.

A method is also preferred which is characterized in that a component with inhomogeneous wall thickness, with at least one corner, with at least one filigree structure, with at least one upset region and / or with at least one toothing is produced. In particular, components with very thin component segments having a thickness of less than 0.1 mm are preferably produced. This is hardly possible with methods known from the prior art. Even with these complicated component geometries results in the process a very good mapping of the tool contours, with only small forces acting on the tool.

Finally, a method is preferred which is characterized in that a blank is selected which comprises a metallic material. Preferably, the blank consists of the metallic material. As a material, in particular metals or metal alloys in question. Particularly preferably, the blank comprises steel or consists of this.

The object is also achieved, in which an apparatus for performing the method according to one of the previously described embodiments with the features of claim 9 is provided. The device is characterized by a high-speed press, which serves to drive an upper tool and / or a cooperating with the upper tool for forming a blank lower tool. A speed for a relative displacement of the lower tool relative to the upper tool is adjustable so that a deformation of the blank is at least partially adiabatic. This results in the advantages that have already been described in connection with the method.

It is possible that the high-speed press only drives the upper tool, with the lower tool being held fast. Alternatively, it is possible that only the lower tool is driven by the high-speed press, the upper tool is held. Finally, an embodiment is possible in which the upper tool and the lower tool are both driven by at least one high-speed drive within a high-speed press, so that they face each other to be relocated. It is essential that a relative displacement between the upper tool and the lower tool can be effected by means of the at least one, preferably exactly one high-speed press, the speed of which is adjustable so that a deformation of the blank is at least partially adiabatic.

Finally, the object is also achieved by providing a component having the features of claim 10. This is characterized in that it is produced by a method according to one of the embodiments described above. This results in connection with the component, the same advantages that have already been described in connection with the method and the device.

The invention will be explained in more detail below with reference to the drawing.

Showing:

1 A schematic representation of an embodiment of a device;

2a) an embodiment of a blank, and

2 B) an embodiment of the blank according to 2a) using the method manufactured component.

1 shows a device 1 that is an upper tool 3 and a lower tool 5 includes. By a press, not shown, the upper tool 3 along a direction indicated by an arrow P relative to the lower tool 5 displaced. This is here designed as a die in which a blank 7 is arranged for forming.

The upper tool 3 is formed as a stamp, which represents a negative mold of a component to be formed together with the die in maximally displaced to each other state, in the form that between the upper tool 3 and the lower tool 5 a space remains, which corresponds to the negative mold, and which in the forming process with the material or material of the blank 7 is filled.

In this case, a relative speed between the upper tool 3 and the lower tool 5 so chosen that the forming of the blank 7 at least partially, preferably completely adiabatically, wherein the forming work is at least partially converted into heat, which in the blank 7 remains, ie during the time of forming not to the environment, in particular to the lower tool 5 or the top tool 3 is delivered. Preferably, a very high impact velocity for the upper tool 3 on the blank 7 which is preferably at least 1 m per second, more preferably at least 2 to at most 100 m per second. The speed values that are necessary for forming a specific blank depend on the size and geometry of the part.

A clock frequency of the device 1 is preferably between at least 10 to at most 800 manufactured components per minute. So are only slight wear of the upper tool 3 and the lower tool 5 very high clock frequencies feasible and numerous components per unit of time manufacturable.

2a) shows an embodiment of the blank 7 , which is formed as a circular plate with a height h. With the arrow P is also in 2 a forming direction indicated along an axis of symmetry A of the blank 7 extends.

2 B) shows an embodiment of a finished component 9 by reshaping the blank 7 using the method in the device 1 is made. The component 9 here has a wall thickness d ₁ in the order of the height h of the blank 7 on. A floor 11 of the component 9 on the other hand has a thickness d ₂ , which is much smaller than the wall thickness d ₁ and thus also much less than the height h of the blank 7 ,

Preferably, in one embodiment of the component 9 the wall thickness d, 0.5 mm, while the thickness d _{2 of} the bottom is about 0.1 mm. This embodiment of the component 9 is preferably made from a blank 7 manufactured, the height h is about 1 mm. Used as a blank 7 a board with 2.5 mm ≤ h ≤ 5 mm, the speed is preferably set between 10 m / s and 20 m / s.

This shows that the component 9 may have a very inhomogeneous cross section, in particular very different wall thicknesses. It is almost like a cup-shaped component here 9 formed with very thin floor. Likewise, it is possible by means of the method readily form corners, or represent filigree structures in particular by radial or axial flow of material. Even upset elements or gears are readily representable.

Overall, it turns out that by using the method and the device 1 a very high flow and form filling capacity of the material of a blank 7 is achievable. In this case, high degrees of deformation and very thin component segments, in particular with thicknesses below 0.1 mm can be realized. It is a very good mapping of the tool contours, in particular given a negative shape of the workpiece, so that a high Endkonturnähe a manufactured component 9 is achievable. This eliminates a costly rework, so that the production of the component is essentially only one stage. At the same time, only small forces act on the device 1 , in particular on the upper tool 3 and the lower tool 5 , so that they can be realized with currently available, conventional materials and need a small space. At the same time, they have a long service life.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007036708 A1 [0002]

Claims (10)

Method for producing a component ( 9 ), with the following steps: arranging a blank ( 7 ) into a lower tool ( 5 ) for the component to be formed ( 9 ); Relocate an upper tool ( 3 ) relative to the lower tool ( 5 ), and forming the blank ( 7 ) to the component ( 9 ), wherein a speed for the relative displacement is chosen so that the deformation of the blank ( 7 ) is at least partially adiabatic. A method according to claim 1, characterized in that the speed is selected so that the deformation of the blank ( 7 ) is completely adiabatic. Method according to one of the preceding claims, characterized in that the speed on forming properties of a material, the blank ( 7 ) or from which the blank ( 7 ) is agreed. Method according to one of the preceding claims, characterized in that the speed is selected depending on the material and a component geometry to be formed. Method according to one of the preceding claims, characterized in that a forming speed of at least 10 ² s ^-1 to at most 10 ⁵ s ^{-1 is} selected. Method according to one of the preceding claims, characterized in that the blank ( 7 ) is preheated, preferably to a temperature of at least 80 ° C to at most 300 ° C. Method according to one of the preceding claims, characterized in that a component ( 9 ) is produced with inhomogeneous wall thickness, at least one corner, at least one filigree structure, at least one upset region and / or at least one toothing. Method according to one of the preceding claims, characterized in that a blank ( 7 ), which comprises a metallic material, preferably consists of a metallic material. Contraption ( 1 ) for carrying out a method according to one of claims 1 to 8, characterized by a high-speed press for driving an upper tool ( 3 ) and / or one with the upper tool ( 3 ) for forming a blank ( 7 ) cooperating lower tool ( 5 ), wherein a speed for a relative displacement of the upper tool ( 3 ) relative to the lower tool ( 5 ) is adjustable so that a deformation of a blank ( 7 ) is at least partially adiabatic. Component ( 9 ) prepared by a process according to any one of claims 1 to 8.

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