EP3519121A1 - Method and device for producing components having an adjusted bottom region - Google Patents

Abstract

The invention relates to a method for producing a component, the method comprising: pre-forming a workpiece (20) into a pre-formed component (10a, 10b, 20') having a bottom region (12, 22), a frame region (14, 24) and optionally a flange region in such a way that the pre-formed component (10a, 10b, 20') has a material excess for the frame region (14) and/or the bottom region (12) and/or optionally the flange region; and calibrating the pre-formed component (10a, 10b, 20') into a component (20") finally formed at least in some regions, having a bottom region (22), a frame region (24) and optionally a flange region; wherein the bottom region of the pre-formed component has substantially the geometry and/or the local cross-sections of the bottom region of the component finally formed at least in some regions. The invention further relates to a device for producing a component, in particular for performing the method.

Description

 Method and device for producing components with adapted

 floor area

The invention relates to a method for producing a component, the method comprising preforming a workpiece into a preformed component having a bottom region, a frame region and optionally a flange region, such that the preformed component has an excess material for the frame region and / or the bottom region and / or optionally the Having flange and calibrating the preformed component to an at least partially final molded component having a bottom portion, a frame portion and optionally a flange. The invention also relates to a device for producing a component,

in particular for carrying out a method according to the invention with a preforming tool for pre-forming a workpiece into a preformed component having a bottom region, a frame region and optionally a flange region, such that the preformed component has a surplus of material for the frame region and / or the bottom region and / or optionally the flange region and with a calibration tool for calibrating the preformed component to an at least partially end-formed component having a bottom region, a frame region and optionally a flange region.

In the production of deep-drawn components, especially open, in

Cross-section U-shaped or hat-shaped profile components, for example by deep drawing it comes after removal of the component from the tool due to the unavoidable elastic recoil mostly to changes in shape, for example in the form of springing between the bottom and the sides of the component or curvatures of the sides and / or soil. As a result, such manufactured components are not sufficiently accurate depending on the application. This effect occurs increasingly in high-strength steel materials or aluminum materials and low sheet thicknesses. To counteract this, a calibration is used in which first a preformed component (preform) with a surplus material (also called material addition or compression addition) is produced, for example by means of a deep drawing. However, occurring during relief of the component, indifferent springback of the component is then subsequently by a calibration step means

Redistributed pressure stress superposition, so that an at least partially finely formed and dimensionally stable component is formed.

In the prior art, when using this method, provision is made in particular for accommodating the excess material for the calibration process in the bottom regions in the form of one or more shafts. When calibrating itself, however, each wave in the ground area collapses again to two or more smaller waves. Depending on the extra lengths produced by the surplus of material, these subsequently fail again in even smaller waves. This effect can be repeated until reaching the end position of the calibration stamp

to repeat.

The described effect is dependent on the size of the excess material, the sheet thickness, the bottom width and the wave height and leads in at least

Area-wise end-formed component to deviations from a uniform and / or smooth surface (area error) in the floor area with negative

Effects on the surface quality in the form of residual ripple,

Surface riots and / or sheet thickness variations or combinations of the above errors.

Against this background, it is an object of the invention, a method and a

Specify device that reduces or avoids the surface defects described and even after the calibration sufficiently smooth surfaces in the bottom area of the calibrated component allows.

The object is according to a first teaching of the invention in a

generic method of the invention achieved in that the bottom area of the preformed component essentially has the geometry and / or the local cross sections of the bottom region of the at least partially end-formed component.

In contrast to the prior art, therefore, the deviating approach is pursued that the bottom region of the preformed component substantially has the geometry of the bottom region of the at least partially final-formed component.

For example, the floor area can be designed plan. The bottom area must be subjected during calibration so no or only a slight change in shape, which is the risk of unwanted surface defects in at least

Area-wise end-formed component further reduced. In other words, the bottom region of the preformed component can be maintained substantially in its shape during calibration. This means that the excess material, for example, predominantly in the region of the foot of the frame and / or the edge or edge region of the floor and For example, even areas in the at least partially final molded component are also provided in the preformed component as a uniform area. Preferably, the excess material is provided only in the edge region of the soil.

The excess material is particularly preferred by the shape of the

Transition region between the bottom portion and the frame portion and / or, if a flange portion is present, provided by the shape of the transition region between the flange portion and the frame portion of the preformed member. It has been shown that in this way the advantages of processes for the production of dimensionally stable components which require little or no trimming can be obtained, but at the same time surface defects in the base region and / or optionally in the flange region can be reduced or even avoided.

The bottom portion of the preformed member preferably has no

Excess material to calibrate or even in the preformed component on a material shortage. The material surplus actually required for the floor area is then preferably essentially through the Transition region between the bottom and the frame portion of the preformed component provided.

A uniform and / or smooth surface is understood here to mean that the shape profile of the surfaces produced according to this invention, in particular of the bottom region of the at least partially final-formed component, only waves with small amplitude, for example less than 0.2 mm, and large wavelength, for example greater than 10 mm.

The workpiece is, for example, a substantially planar board, for example a sheet metal. Preferably, the workpiece is made of a steel material. However, other metal materials, such as aluminum, can also be used. The component is preferably a sheet metal component.

The preforming is carried out in particular by means of a thermoforming forming, which can be carried out, for example, single-stage or multi-stage. Any combinations of drawing, embossing, lifting, edging and / or bending are also conceivable. The way to produce the preformed component can therefore be taken individually. The preformed component obtained by the preforming can in particular be regarded as a component substantially close to the final shape which, with the exception of the smallest possible deviations, essentially already has the intended geometry.

Calibration can thus be understood to mean, in particular, a finish-forming or final shaping of the preformed component, which can be achieved, for example, by one or more pressing operations. The calibration includes in particular a compression process. For example, the frame region, the bottom region, optionally the flange region and / or the transition regions of the preformed component are subjected to compression.

However, it is possible that the at least partially final molded component can be subjected to further processing steps, such as a Introduction of connection holes and / or a trimming process and / or a post-forming, such as pressing and / or bending. However, preferably no further main shaping steps are necessary.

The preforming and calibrating described preferably takes place successively.

According to a preferred embodiment of the method according to the invention, the shape of the transition region between the bottom region and the frame region of the preformed component leads to a raised or lowered bottom region of the preformed component. As a result, sufficient excess material in the transition region can be introduced into the preformed component, without, however, having to modify the geometry of the entire bottom region for this purpose. Rather, the floor area can be raised or lowered altogether. Preferably, a raised floor area is achieved by a cross-sectionally substantially U-shaped transition area. In particular, one is over the entire

Ground area provided substantially uniform lifting or lowering. The bottom region of the preformed component is raised or lowered in particular compared to the Zargenfuß. Compared to the bottom area of the

As seen in the finished molded component, the bottom region of the preformed component is thus also raised or lowered in particular. Under a raised or lowered floor area is in particular starting from the same

Zend end level or Zargenkopf (length level) understood compared to the lower ground level (zero level) of a component in which the same material excess is achieved by one or more over the entire ground area extending bumps, raised or lowered floor area.

According to a preferred embodiment of the method according to the invention, the material excess is provided substantially or exclusively by the transition region between the bottom region and the frame region of the preformed component. As a result, in particular, no further geometric

Modifications in the bottom area of the preformed component to provide a Material excess required. This allows in particular a low-defect and smooth floor area on the at least partially final-formed component.

According to a preferred embodiment of the method according to the invention, the shape of the transition region between the bottom region and the frame region of the preformed component provides an additional length for the bottom region and / or the frame region of the preformed component when viewed in cross-section.

The fact that an excess of material in the form of an additional length is provided, the risk of material defects and uneven surfaces on at least partially final molded component is further reduced, for example in

Contrary to a surplus of material in the form of waves distributed in the floor area.

According to a preferred embodiment of the method according to the invention, a material flow into the frame region of the preformed component is achieved by calibrating the preformed component to the at least partially end-formed component. For example, the material flow takes place from the transition region and / or the bottom region of the preformed component. This can on the one hand have the advantage that no additional extension of the frame region of the preformed component is necessary due to the material surplus, since sufficient material in the frame region can be provided by the flow of material.

According to a preferred embodiment of the method according to the invention, the preforming by a deep-drawing-like operation with or without hold-down

carried out. By preforming with preferably distanced holddowns, the material guide is improved and the process stability improved. at

Components with a simple geometry, such as, for example, in cross-section U-shaped or hat-shaped components, but can be dispensed with the hold-down during deep drawing. This design is also called, for example, as embossing the floor with bumps of the frames. This process can optionally be displayed in one or more process steps. According to a preferred embodiment of the method according to the invention, the bottom region of the preformed component is subjected to a force during the calibration, which allows a compression of the bottom region of the preformed component and essentially avoids a collapse of the material excess. For example, the bottom area is acted on both sides with force. As a result, a consolidation in the soil area is achieved when upsetting the soil, but without provoking surface defects.

According to a preferred embodiment of the method according to the invention, the preforming is carried out in a preforming tool comprising a preforming punch, a preforming die and a preforming die movable relative to the preforming die, the workpiece being located between the preforming punch and the preforming die. Gesenkboden is arranged and whereby by a

Relative movement between the workpiece with the preform punch and the preform Gesenkboden on the one hand and the preform die on the other hand

Workpiece is preformed. For example, the workpiece is between the

Fixed preform punch and the preform Gesenkboden, for example, clamped. In addition, hold-downs or blank holders can optionally be provided, which enable a more reliable forming, especially in the case of more complex component geometries. By means of the execution, the preforming with low

Process technical effort to be realized and in particular in

press-based procedures are integrated.

According to a preferred embodiment of the method according to the invention, the calibration is carried out by a calibration tool comprising a calibration punch, a calibration die and a calibration die movable relative to the calibration die, the preformed component being placed between the calibration punch and the calibrator It is arranged on a false floor, and wherein the preformed component is calibrated by a relative movement between the preformed component with the calibration punch and the calibration die bottom, on the one hand, and the calibration die, on the other hand. In particular, by a separate version of the calibration die and the calibration die bottom can be used during calibration acting forces are precisely controlled temporally and locally. In addition, by means of the embodiment, the calibration can also be realized with a low process outlay and, in particular, can be integrated in the press-based method.

According to a preferred embodiment of the method according to the invention, for calibrating the preformed component, the frame region of the at least partially demoulded component defining calibration Gesenkzargen the calibration tool are fed to each other. The preformed component can thus first be inserted into the calibration tool when the calibration die frames are open, which can then be closed. This makes it possible, in particular, to insert even heavily sprung components reliably into the calibration tool.

According to a preferred embodiment of the method according to the invention, the calibration die frames used for calibrating the preformed component of the calibration tool can be configured such that the calibration die frames can preferably be moved in the optional flange region of the preformed component.

According to a second teaching of the invention, the object mentioned in a generic device is achieved in that the preforming tool is designed for preforming the workpiece, that the material surplus essentially by the shape of the transition region between the bottom portion and the frame portion and optional in Essentially by the shape of the

Transition region between the flange portion and the frame portion of the preformed member is provided. For example, this is through the

Geometry of the preform tool, for example, the preform punch and / or the preform die bottom of the preform tool achieved. As already stated, the material excess is thus not distributed over the entire bottom area of the preformed component (for example in the form of one or more shafts) as before, but rather instead is provided in the Transition region substantially between the bottom portion and frame portion and optionally provided substantially by the shape of the transition region between the flange portion and the frame portion of the preformed component. Thus, the advantages of processes for the production of dimensionally stable components can be combined with further reduced or even avoided area errors in the floor area.

According to a preferred embodiment of the device according to the invention, the preforming tool comprises a preforming punch, a preforming die and a preforming die base movable relative to the preforming die. This makes it possible to arrange and preferably fix the workpiece between the preform punch and the preform die bottom and to preform the workpiece by a relative movement between the workpiece with the preform punch and the preform die bottom on the one hand and the preform die on the other hand.

Optionally, the preforming tool also has, in particular, outer hold-downs or sheet-metal holders which, in particular in the case of complex component geometries

Material flow can control positive to ensure a particular wrinkle-free forming. By means of the execution, the preforming with low

process technical effort can be realized and the preforming tool can be integrated in particular in a press.

According to a preferred embodiment of the device according to the invention, the calibration tool comprises a calibration punch, a calibration die, and a calibration die base movable relative to the calibration die. As a result, the preformed component can be arranged and preferably fixed between the calibration punch and the calibration die base. By a

Relative movement between the preformed component with the calibration stamp and the calibration die bottom on the one hand and the calibration die on the other hand, the preformed component can then be calibrated. As already stated, a separate design of the calibration die and the calibration die bottom allows the forces acting during calibration to be precisely controlled in terms of time and location. In addition, the calibration with low procedural Effort can be realized and the calibration tool can be integrated in particular in a press.

According to an alternative embodiment of the device according to the invention can be dispensed with the movable calibration Gesenkboden. In order to introduce the preformed component into the tool in the calibration process, in this case leading, spring-loaded shaped pieces can be provided in the calibration punch, which press the component into the die in advance. The spring-loaded fittings are then displaced when closing the tool in the stamp. This results in a simpler tool design.

According to a preferred embodiment of the device according to the invention, the calibration die comprises at least two separate, mutually movable calibration Gesenkzargen. The preformed component can thus first be inserted into the calibration tool when the calibration die frames are open, which can subsequently be closed, which facilitates the insertion of highly resilient, preformed components.

With regard to further embodiments of the device according to the invention, reference is made to the comments on the method according to the invention.

By the preceding and following description of method steps according to preferred embodiments of the method, corresponding means for carrying out the method steps by preferred embodiments of the device should also be disclosed. Likewise, by the disclosure of means for carrying out a method step, the corresponding method step should be disclosed.

In addition, the invention will be explained in more detail using an exemplary embodiment in conjunction with the drawing. The drawing shows in Fig. La-c is a schematic representation of a calibration according to the prior art;

2a is a schematic representation of a preformed component according to the

 State of the art;

Fig. 2b, c are schematic representations of exemplary preformed components

 Embodiments of inventive method;

3a, b schematic representations of an exemplary preforming tool and an exemplary calibration tool according to an embodiment of a device according to the invention; and

4a-j is a schematic representation of a sequence of an embodiment of a method according to the invention.

Fig. La-c first shows a schematic representation of a calibration according to the prior art. In the prior art, it is provided to provide a surplus of material for the calibration process in the form of one or more waves in the bottom regions of a preformed component 1 and thus over the entire

When calibrating by means of an upsetting punch 2 and an upsetting die 4, however, each shaft in the bottom region of the component 1 collapses again into two or more smaller waves (Figure 1b), failing according to additional lengths produced by the surplus of material These in turn in turn into two even smaller waves of higher order (Figure lc) .This effect can be repeated several times until reaching the end position of the calibration stamp.

FIG. 2 a shows a schematic representation of the preformed component 1 from FIG. 1 according to the prior art. The component 1 has in particular in his

Ground area excess material in the form of a spread over the entire

Ground area extending bump. The dashed line 6 shows the Zargenendenniveau or length level aligned at the Zargenende. The dashed line 8 indicates the below ground level (zero level) of the preformed component 1.

FIGS. 2b, c now show schematic representations of exemplary preformed components 10a, 10b, which are produced in the context of exemplary embodiments of methods according to the invention. In the components 10a, 10b of the

Excess material due to the shape of the transition region 16 between the

Bottom portion 12 and the frame portion 14 of the preformed member provided. The shape of the transition region 16 between the bottom portion 12 and the

Frame portion 14 of the preformed components 10a, 10b leads to a on the

Zero level raised (Fig. 2b) and lowered below the zero level 8 (Fig. 2c) bottom portion of the preformed component. The excess material is thereby exclusively through the respective transition region 16 between the

Bottom portion 12 and the frame portion 14 of the preformed member 10, 10 b provided. The bottom region 12 of the preformed component 10a, 10b is in each case designed in a planar manner and therefore essentially already has the intended plane desired geometry of the at least partially demoulded bottom region. The additional length provided by the excess material in cross-section for the frame area and the floor area is the same in FIGS. 2a to 2c.

In the following, an exemplary embodiment of a device according to the invention and an exemplary embodiment of a method according to the invention will be described in conjunction with FIGS. 3 and 4. 3a, b show schematic representations of an exemplary preform tool 30 and an exemplary calibration tool 40 according to an embodiment of a device according to the invention, while FIG. 4 shows a schematic representation of a sequence of an embodiment of a method according to the invention.

The preforming tool 30 is configured for preforming a workpiece 20 into a preformed component 20 'having a bottom portion 22 and a frame portion 24 such that the preformed member 20' provides a surplus of material for the workpiece Zargenbereich 24 and / or the bottom portion 22 has. The preform tool 30 includes a preform punch 32, a preform die 34, and a preform die bottom 36 movable relative to the preform die 34. The preform tool 30 also includes an optional hold down 38. The elevatable preform die bottom 36 is thereby modified in its shape so that by means of the preforming tool, a shaping according to Fig. 2b (or alternatively corresponding to 2c) is achieved.

Alternatively and not shown here, the production of the preformed component in a first step by means of at least partially embossing the bottom portion and in a second or further step, raising or folding the

Zargenbereiches done.

The calibration tool 40 is used to calibrate the preformed component 20 'to an at least partially final molded component 20 "with a bottom portion 22 and a frame portion 24. The calibration tool 40 includes a calibration punch 42, a calibration die 44 and a relative to the calibration The calibrating die bottom 46 may be moved by suitable means such as external fixed distances distanced to the calibration punch 42. The calibration die 44 comprises two separate, mutually movable and laterally deliverable calibration die frames 44a. 44b

During the course of the process, the calibration tool 40 may close, and the calibration punch 42 may displace the calibration die bottom 46 with the preformed component therebetween into the then closed calibration die frames 44a, 44b (see also FIG Floor portion 22 of the preformed component is leveled and the frame portion 24 is compressed to the nominal size (see also Fig. 4h).

In the course of the process, first of all the movable preform die bottom 36 is extended to the level of the die support surface of the preform die 34 or just beyond. Subsequently, the workpiece 20 (board) is inserted into the preforming tool 30 (FIGS. 3 a, 4 a) and, optionally, between the fixed spacers Preform die 34 running down holders 38, secured to guide pins and / or holes against displacement (Fig. 4b). In the case of simply designed components (predominantly u- or hat-profile-shaped components), it is possible to dispense with the optionally spaced-down device 38 and to carry out the so-called embossing with abutments. In the process, only pins on edges or holes secure the workpiece 20 between the preform punch 32 and the preform die bottom 36 until the workpiece 20 is positively pressed into place.

Furthermore, the composite of preform punch 32 and preform die bottom 36 now sinks into the lower end position (FIG. 4 c). This leads to the formation of the frame regions 24 of the preformed component 20 '. Then that can

preformed component 20 'are removed from the preforming tool 30. In this case, in particular in the frame region 24 springback occurs (FIGS. 4d, 4e). The preformed component 20 'is now introduced into the calibration tool 40.

The calibration die base 46 has already been defined before the preformed component 20 'is inserted and raised to a height which makes contact with the inserted base region 22 of the preformed component 20'. Then, the feed with the preformed member 20 ', wherein the preformed member 20' at the beginning of the process preferably in a stable position between the two calibration Gesenkzargen 44a, 44b and the calibration die bottom should be 46 (Fig. 3b, Fig. 4f ).

Subsequently, the calibration punch 42 and the calibration die bottom 46 are spaced apart against each other, wherein the bottom portion 22 of the preformed member 20 'is secured and not clamped substantially. This allows a largely free flow of material in the bottom region 22 without inhibiting the subsequent calibration effect, but essentially prevents the formation of waves in the bottom region 22 by the resulting compressive stress during calibration. After the calibration punch 42 has secured the bottom area 22 of the preformed component 20 'between itself and the raised calibration die base 46 against rough slippage, the two calibration die frames 44a, 44b move so far against the calibration punch 42 until it is exactly defined calibration gap between the calibration Gesenkzargen 44 a, 44 b and the calibration punch 42 sets and the spring-loaded Zargenbereich 24 of

preformed member 20 'are aligned therein (Fig. 4g).

In the further course of the calibration stamp 42 lowers to its end position down. He displaces the raised, but distanced to the calibration punch 42 out and with a sufficient counterforce (to maintain the distancing) provided calibration die bottom 46 also down. Only in the last section of this path is the elevation of the bottom portion 22 of the preformed member 20 'eliminated by flowing the material mainly over the transition region 26 towards the frame portion 24 (Figure 4h). The

Counterforce of the calibration die bottom 46 is preferably to be chosen so large that the compression of the preformed member 20 'can also act in the composite of calibration punch 42 and calibration die bottom 46, but at the same time not to collapse the surplus material in waves cause.

The flow of the material mainly in the transition region 26 has several advantages. On the one hand, the bottom region 22 of the preformed component 20 'essentially remains in its shape. Furthermore, the material displacement in the frame area 24 may be selected to be so great that an extension of the

Zargenbereichs possibly also can be omitted. Ultimately, the flow of material in the transition region 26 can be used to positively influence the angle of attack of the frame region 24 to the bottom region 22.

At the bottom dead center, the component 20 "is finally finally at least partially finished and completely calibrated, so that the upsetting process has taken place in a targeted manner and the residual ripple in the ground is considerably reduced or even completely avoided (FIG. 4i, j).

The exemplary method and the exemplary device have been explained in more detail here with reference to a flangeless component. Flange-mounted components are subject to an analogous procedure.

Claims

 P a n t a n s p r e c h e

Method for producing a component, the method comprising

 Preforming a workpiece (20) to a preformed member (10a, 10b 20 ') having a bottom portion (12, 22), a frame portion (14, 24) and optionally a flange portion, so that the preformed component (10a, 10b 20') Excess material for the frame portion (14) and / or the bottom portion (12) and / or optionally has the flange portion; and calibrating the preformed component (10a, 10b, 20 ') to a component (20 "), which is at least partially end-formed, with a bottom region (22), a frame region (24) and / or optionally a flange region;

characterized,

 that the bottom region (12, 22) of the preformed component (10a, 10b, 20 ') has substantially the geometry and / or the local cross sections of the bottom region (22) of the at least partially final-shaped component (20 "), wherein

the excess material due to the shape of the transition region (16, 26) between the bottom region (12, 22) and the frame region (14, 24) of the preformed component (10a, 10b 20 ') and / or by the shape of the

Transition region between the flange portion and the frame portion of the preformed member is provided.

A method according to claim 1, characterized in that the shape of the transition region (16, 26) between the bottom portion (12, 22) and the frame portion (14, 24) of the preformed component (10a, 10b 20 ') to a raised or lowered floor area (12) of the preformed component (10a, 10b 20 ') leads.

Method according to claim 1 or 2, characterized in that the

Excess material essentially through the transition region (16, 26) between the bottom region (12, 22) and the frame region (14, 24) of the preformed component (10a, 10b, 20 ') is provided.

4. The method according to any one of claims 1 to 3, characterized in that the shape of the transition region (16, 26) between the bottom region (12, 22) and the frame region (14, 24) of the preformed component (10a, 10b 20 ') seen in cross-section provides an additional length for the bottom portion (12, 22) and / or the frame portion (14, 24) of the preformed component (10a, 10b 20 ').

5. The method according to any one of claims 1 to 4, characterized in that the preforming is carried out by a deep-drawing-like operation with or without hold-down (38).

6. The method according to any one of claims 1 to 4, characterized in that the preforming is performed as a combination of at least partially embossing the bottom portion and raising the Zargenbereichs.

7. The method according to any one of claims 1 to 6, characterized in that the bottom portion (12, 22) of the preformed component (10a, 10b 20 ') is acted upon during calibration with a force which a compression of the bottom portion (12, 22 ) of the preformed component (10a, 10b 20 ') and prevents collapse of the excess material.

8. The method according to any one of claims 1 to 7, characterized in that the preforming in a preforming tool (30) comprising a preform punch (32), a preform die (36) and a relative to the preform die (34 movable preform die bottom (36), wherein the workpiece (20) is disposed between the preform punch (32) and the preform die bottom (36) and wherein, by relative movement between the workpiece (20) and the preform Stamp (32) and the Preform die bottom (36) on the one hand and the preform die (34) on the other hand, the workpiece (20) is preformed.

9. The method according to any one of claims 1 to 8, characterized in that the calibration by a calibration tool (40) comprising a calibration punch (42), a calibration die (44) and a relative to the calibration die (44 movable calendering die bottom (46), wherein the preformed component (10a, 10b, 20 ') is positioned between the sizing die (42) and the calibration die bottom (46), and wherein relative movement between the preformed component (10a, 10b 20 ') with the calibration punch (42) and the calibration die base (46) on the one hand and the calibration die (44) on the other hand, the preformed component (10a, 10b 20') is calibrated.

10. The method according to claim 9, characterized in that for calibrating the preformed component (10a, 10b, 20 ') the Zargenbereich (24) of the at least partially end-formed component (20 ") defining Kalibrier- Gesenkzargen (44a, 44b) of the calibration Tool (40) to each other

 be closed.

11. The method according to claim 10, characterized in that the

 Calibration of the preformed component (10a, 10b, 20 ') used calibration Gesenkzargen (44a, 44b) of the calibration tool (40) are designed such that the calibration Gesenkzargen can be moved preferably in the optional flange portion of the preformed component.

12. An apparatus for producing a component, in particular for carrying out a method according to one of claims 1 to 11,

with a preforming tool (30) for preforming a workpiece (20) into a preformed component (10a, 10b, 20 ') having a bottom portion (12, 22), a frame portion (14, 24) and optionally a flange portion, such that the preformed component Component (10 a, 10 b 20 ') a surplus of material for the frame region (14, 24) and / or the bottom region (12, 22) and / or optionally has the flange region; and

 with a calibration tool (40) for calibrating the preformed component (10a, 10b 20 ') to a component (20 "), which is at least partially deformed, with a bottom region (22), a frame region (24) and optionally a flange region;

 characterized,

 in that the preforming tool (30) is designed in such a way for preforming the workpiece (20) that the excess of material is determined essentially by the shape of the transitional region (16, 26) between the base region (12, 22) and the frame region (14, 24). and optionally provided substantially by the shape of the transition region between the flange portion and the frame portion (14, 24) of the preformed member (10a, 10b, 20 ').

13. The apparatus according to claim 12, characterized in that the preforming tool (30) has a preforming punch (32), a preforming die (34) and a preforming die base (36) movable relative to the preforming die (34). includes.

14. The apparatus of claim 12 or 13, characterized in that the calibration tool (40) has a calibration punch (42), a calibration die (44) and a relative to the calibration die (44) movable Kalibriergeenkboden ( 46).

15. The apparatus of claim 14, characterized in that the calibration die (44) comprises at least two separate, mutually movable calibration Gesenkzargen (44a, 44b).