DE102021133789A1 - Process for the production of sheet metal components and device therefor - Google Patents

Abstract

The invention relates to a method and a device for producing sheet metal components (3) with essentially reduced springback.

Description

technical field

The invention relates to a method and a device for producing sheet metal components.

Technical background

Methods and devices for the production of dimensionally stable sheet metal components are disclosed in the prior art, see for example DE 10 2007 059 251 A1 , DE 10 2008 037 612 A1 , DE 10 2009 059 197 A1 , DE 10 2013 103 612 A1 , DE 10 2013 103 751 A1 , wherein the production is carried out in at least two stages (forming processes). In the first stage, an in particular flat blank is formed into a preform. Compared to the sheet metal component geometry to be finally produced, the preform has a surplus of material that is distributed as evenly as possible. In the second stage, the so-called calibration, this excess material is compressed, particularly in the direction of the plane of the sheet. The inhomogeneous state of stress in the preform is realigned and the undesired, batch-dependent springback of the sheet metal component, which occurs in particular with high-strength materials in combination with low material thicknesses, is largely avoided.

When calibrating sheet metal components with (welding) flanges, lateral slides are usually brought up to the calibration stamp via wedge drivers when the calibration tool is closed and remain there during the calibration process. The edge of the preform flange is supported on the slide during calibration, which means that the compressive stress superimposition is realized by compressing the excess material. The contact between the preform and the slide is exclusively in the area of the edge of the preform flange. A satisfactory concept does not yet exist for sheet metal components with sections or significant areas without a (weld) flange. The previous concepts envisage producing a preform which essentially corresponds to the final geometry, with the preforming tool being designed with its effective surfaces essentially on the effective surfaces of the calibration tool.

Summary of the Invention

The invention is therefore based on the object of providing a generic method and a generic device with which dimensionally stable sheet metal components can be produced which are flangeless at least in sections.

• This problem is solved by a generic method with the features of patent claim 1.
• This problem is solved by a generic device with the features of patent claim 6.

According to the teaching of the method according to the invention, it is provided that the method for producing a sheet metal component comprises at least two steps: Preforming a sheet metal into a sheet metal preform in a preforming tool, the sheet metal preform being designed as an open profile with an opening and in its longitudinal extension at least one flangeless section and has excess sheet metal material at least in regions; and final forming of the sheet metal preform into a sheet metal component in a calibrating tool comprising at least one calibrating stamp and at least one calibrating die, in which the excess sheet metal material in the sheet metal preform is compressed by relative movement between the calibrating stamp and calibrating die, with the edge of the sheet metal preform present at least in the flange-less section being compressed during the final forming comes into contact with a stamp shoulder of the calibration stamp by relative movement, is supported on it and is subjected to pressure, in particular in order to be upset.

It has been found that dimensionally stable sheet metal components can be produced which are flangeless at least in sections and, in particular, can be calibrated or finish-formed with a rather small frame opening angle of less than 6° with a simplified calibration tool design. During upsetting or calibrating by superimposing compressive stress, at least the edge of the sheet metal preform present in the flangeless section can be supported on the stamp shoulder of the calibrating stamp. It should be noted that during the calibration process, when the calibration tool is closed, the sheet metal preform is not pinched between the calibration stamp and the calibration die, which would damage the finished sheet metal component and/or the calibration tool.

The frame opening angle is the maximum angle by which the sheet metal component frame can be rotated inwards in relation to the effective direction of the calibration tool (press ram) around an axis oriented in the longitudinal extension of the sheet metal component in the transition area between frame and sheet metal component base before an undercut occurs in the tool.

Viewed in cross section, the sheet metal preform as well as the final sheet metal component shows at least a floor and at least two protruding frames, each with a transition between the floor and the two frames. Furthermore, depending on the design of both the sheet metal preform and the final sheet metal component, there is at least one flangeless section in the longitudinal extent. This means that either local sections can be designed without flanges on one or both sides, or one side can be designed completely without flanges and/or optionally the other side can be designed without flanges only in part. In particular, the sheet metal preform and also the final sheet metal component can be designed without flanges. For example, a flange can be connected to one of the frames and at least in sections, in which case the sheet metal preform as well as the final sheet metal component can have a transition between the frame and flange at least in sections. The final sheet metal component preferably has sections with and without a flange. The flangeless section can thus also be understood as being only on one side of the sheet metal preform, with the sheet metal preform also not being able to have a flange on both sides, at least locally viewed in cross section, depending on the design.

The sheet metal preform can be produced in one or more steps by means of any combination of shaping processes. The preforming can, for example, include a deep-drawing-type shaping step. In particular, a multi-stage shaping can also be carried out, comprising for example embossing of the base to be created and raising of the frames to be created or placement of the flanges to be created optionally in sections. Any combinations of folding and/or bending and/or (ver) embossing are also conceivable. The deep-drawing-like shaping carried out for preforming, for example, can in particular be carried out in one or more stages. Forming can preferably be carried out without active material flow control for the production of the sheet metal preform. Depending on the design, the preforming tool must then be designed accordingly.

Finish forming of the sheet metal preform means upsetting/calibrating, which can be achieved, for example, by one or more pressing processes. Excess sheet metal material is provided at least in regions in the sheet metal preform produced. The excess sheet metal material in the sheet metal preform has, at least in certain areas, a developed length in cross section which is between 0.5% and 6% longer in relation to the developed length of the finished sheet metal component (target geometry). The developed length of the cross sections of the sheet metal preform considered in this way is in particular between 0.7% and 4.3% longer than that of the finished sheet metal component. If, as a result of the process control during the production of the sheet metal preform, the developed length of the cross sections varies too much, if the developed length is too short, there would not be enough excess sheet material available for the subsequent final forming, which would impair the dimensional accuracy of the final sheet metal component. If, on the other hand, the unwound length of the cross-section of the sheet metal preform under consideration is too great, the oversized sheet metal material would collapse into waves during the subsequent final forming, which can mean an optical and/or dimensional defect. In addition, there is an increased risk of tool damage due to excessive compression forces or protruding, crushed sheet metal component areas, such as sheet metal edges.

The essentially completely formed sheet metal component can in this respect be understood as a finally formed sheet metal component. However, it is possible that the finished sheet metal component can be subjected to further processing steps that modify the sheet metal component, such as the introduction of connection holes and/or a small final trimming and/or the implementation of secondary shaping steps such as the introduction of additional, local embossing or For example, placing flanges on the sheet metal component ends.

The sheet metal preform produced and the finished sheet metal component essentially have a longitudinal extent and a transverse extent, with the longitudinal extent being greater than the transverse extent in most sheet metal components in terms of dimensioning. Thus cross-section means a cut through the transverse extension of the sheet metal preform/sheet metal component.

The sheet metal preform is placed in the calibration tool in such a way that its opening points downwards and is positioned on the calibration stamp. The advantage of inserting the sheet metal preform produced as an open profile with the opening facing downwards is that the sheet metal preform can be positioned better and more easily. In particular, the calibrating die is stationary and the calibrating die is designed to be movable in the calibrating tool.

Since the upsetting/calibrating force generated during final forming is conducted into the sizing die via the edge of the sheet metal preform, at least in the flangeless section, an excessively large gap between the edge of the sheet metal preform in the sizing die and, in particular, the vertical die cheek of the sizing die positioned above would damage the sheet metal component and thus excessive wear or damage of the calibration tool. According to one embodiment of the method according to the invention, it is provided that the calibrating die during the relative movement at least in the area of the flangeless section of the sheet metal preform with the smallest possible gap, which can correspond in particular to between >0% and 20% of the material thickness of the sheet metal used, on the stamp shoulder of the calibrating stamp before the final forming begins by upsetting the excess sheet metal material additionally introduced into the sheet metal preform. As a result, the edge of the sheet metal preform is surrounded on all sides by stable tool surfaces, especially before the start of final forming, before the edge of the sheet metal preform is supported on the stamp shoulder on the calibration stamp during final forming and a final sheet metal component geometry can be generated in the actual calibration process.

According to one embodiment of the method according to the invention, the sheet metal preform is provided with a base which, during the course of the preforming, is subjected to excess sheet metal material, at least in the flangeless section, in such a way that a base area that bulges in the direction of the opening has been produced during the preforming, so that the Sheet metal preform is positioned at least over the bulging bottom area at least in the area of the flangeless section of the sheet metal preform on the calibrating stamp in such a way that the edge of the sheet metal preform present at least in the flangeless section is arranged above the stamp shoulder. At least in the flange-less section, the bottom of the preform can have excess sheet metal material distributed as evenly as possible in the bottom (area) which, for example, in the course of the production of the sheet metal preform with 2 to 5% material addition (relation of developed length of sheet metal preform ↔ sheet metal component) has been applied in order to to realize a superimposition of compressive stress during final forming in the calibrating die, preferably in such a way that the protruding base area is positioned on the calibrating die before the actual final forming begins in such a way that the frame(s) of the sheet metal preform is/are securely positioned above the die shoulder on the calibrating die while the calibrating die is closing and so that jamming between the calibration die and the calibration stamp can be reliably prevented.

According to an alternative or additional embodiment of the method according to the invention, the sheet metal preform is provided with a base in which embossings pointing in the direction of the opening have been produced locally or in sections during the preforming, so that the sheet metal preform is positioned at least via the embossings on the calibration stamp in such a way that the edge of the sheet metal preform present at least in the flangeless section is arranged above the stamp shoulder. The embossing made locally or in sections during preforming in the base of the preform can be distributed along the length of the base or only as a local or sectional embossing at the two ends of the sheet metal preform viewed in the longitudinal extent. In this way, compressive stress can be superimposed during final forming in the calibrating tool, so that before the actual final forming begins, the sheet metal preform is positioned on the calibrating stamp via the embossing in the base in such a way that the frame(s) of the sheet metal preform is/are safely above the stamp shoulder on the calibrating stamp while the calibrating tool is closing is arranged so that pinching between the calibration die and the calibration stamp can be reliably prevented.

According to a further alternative or additional embodiment of the method according to the invention, the sheet metal preform is provided with a base, with at least a partial area of the base being fitted with at least one adjustable insert which is arranged in the calibration stamp when the sheet metal preform is inserted into the calibration tool and which is spaced apart from the calibration stamp when the sheet metal preform is inserted. comes into contact and the sheet metal preform is positioned on the insert at least over the partial area of the base at least in the area of the flangeless section of the sheet metal preform in such a way that the edge of the sheet metal preform present at least in the flangeless section is arranged above the stamp shoulder. The one or more inserts arranged in the calibration stamp can be spring-loaded or driven, for example by a wedge driver, hydraulically, pneumatically, electromechanically, electromagnetically, and additionally or alternatively used to realize a compressive stress superimposition during final forming in the calibration tool, preferably in such a way that the sheet metal preform beginning of the actual final forming is positioned on the calibrating stamp in such a way that the frame(s) of the sheet metal preform is/are positioned securely above the stamp shoulder on the calibrating stamp while the calibrating tool is being closed, thus reliably preventing jamming between the calibrating die and the calibrating stamp.

In order to reliably prevent the frame(s) from being jammed between the calibration die and calibration stamp, at least one of the three aforementioned configurations is preferred, comprising a sheet metal preform with a protruding base area, a sheet metal preform with local or sectional embossing in the base and/or adjustable inserts to be taken into account in the calibration stamp when positioning the sheet metal preform on the calibration stamp.

The task mentioned at the outset is achieved with a device of the generic type, with at least one preforming tool for preforming a metal sheet into a sheet metal preform, the sheet metal preform being designed as an open profile with an opening and having at least one flangeless section and at least some excess sheet metal material in its longitudinal extension; and with at least one calibrating tool for finish-forming the sheet metal preform into a sheet metal component, the calibrating tool comprising at least one calibrating stamp and at least one calibrating die, the excess sheet metal material in the sheet metal preform being compressed by the relative movement between the calibrating stamp and calibrating die, with the sheet metal preform having its opening pointing downwards can be positioned on the calibration stamp, the calibration stamp having at least one stamp shoulder, which is provided at least in the flangeless section of the sheet metal preform, so that the edge of the sheet metal preform, which is present at least in the flangeless section, can be brought into contact with a stamp shoulder of the calibration stamp by the relative movement and can be supported on it and can be subjected to pressure.

A final sheet metal component is preferably produced with a profile that opens downwards in the calibration tool (press position), so that the calibration stamp is arranged at the bottom and the calibration die at the top in the calibration tool and can be moved relative to one another. Thus, the calibrating die is preferably attached to a press table and the calibrating die to one on the press ram of the calibrating tool designed as a press. Depending on the design of the sheet metal component to be produced, at least sections are flangeless, although sections with a flange can also be present, so that if there are sections with a flange, on one or both sides, corresponding sections in the calibration tool are adapted to the flange section in order to also to be able to realize a compressive stress overlay in the at least partial flange section. Preferably, the calibrating tool is designed in a correspondingly segmented manner in order to be able to finish-form flangeless sections and possibly also existing flanged sections on a sheet metal preform into a sheet metal component.

In order to avoid repetition, reference is made to the statements on the method according to the invention.

According to one embodiment of the device, the calibration stamp can have at least one adjustable insert which is arranged in the calibration stamp and can be spaced apart from the calibration stamp. In particular, the at least one insert can be moved relative to the calibration stamp. The element(s) arranged in the calibration stamp can be driven, for example, via the ram stroke and/or additional control units, which can be driven, for example, by means of springs, wedge drivers, hydraulics or pneumatics. A defined distance between the sheet metal preform and the calibration stamp can be set via the element, with which a spacing of the edges provided in particular in the flange-less section from the stamp shoulder of the calibration stamp can be set. In the course of the final forming or the closing of the calibration tool, the element is inserted completely flush in the calibration stamp.

According to one embodiment of the device, the calibration die can be made in several parts and have at least one adjustable die cheek, at least in the flangeless section of the sheet metal preform. For example, the die beam can act as a leading shut-off to ensure that the edge of the sheet metal preform is securely located above the punch shoulder when the leading die beam has passed the punch shoulder and a closed sizing gap has thus closed.

According to one embodiment of the device according to the invention, the stamping shoulder has a maximum extent of the material thickness of the metal sheet used plus >0 mm to 0.35 mm, in particular 0.01 to 0.20 mm, preferably 0.02 to 0.10 mm. In this way, it can preferably be ensured that when the compressive stress is superimposed, the excess sheet metal material can flow right into the edge of the sheet metal component, and in particular that local thickening of the sheet metal preform during the calibration is also permitted without tilting or other negative effects (damage to the sheet metal component and / or tool) arise in particular when opening the calibration tool and / or when removing the sheet metal component from the calibration tool.

According to one embodiment of the device according to the invention, the device is integrated in a press line or transfer press. In particular in the production of mass products, for example for products in the automotive industry, products such as sheet metal components are produced particularly economically in press lines or transfer presses. The device according to the invention can be used economically in existing production lines in the form of interchangeable inserts which provide at least one preforming tool and at least one calibrating tool. Also the use of the device according to the invention in progressive presses is conceivable.

character list

• 1 eine schematische perspektivische Darstellung zur Erzeugung einer Blechvorform,
• 2 bis 5 eine Abfolge von Schritten zu unterschiedlichen Zeitpunkten zur Herstellung eines Blechbauteils gemäß einer Ausführung eines erfindungsgemäßen Verfahrens und eine erfindungsgemäße Vorrichtung in einer schematischen Schnittdarstellung und in einer schematischen perspektivischen Darstellung ein Teilausschnitt der Vorrichtung und
• 6 eine schematische perspektivische Darstellung eines Blechbauteils.

The invention is explained in more detail below with reference to drawings. Identical parts are provided with the same reference symbols. Show in detail:

• 1 a schematic perspective representation for the production of a sheet metal preform,
• 2 until 5 a sequence of steps at different points in time for the production of a sheet metal component according to an embodiment of a method according to the invention and a device according to the invention in a schematic sectional view and in a schematic perspective view a partial section of the device and
• 6 a schematic perspective view of a sheet metal component.

Description of the Preferred Embodiments

In 1 is a schematic perspective view of the production of a sheet metal preform (2) from a metal sheet (1) in a preforming tool (10) not shown in detail. The sheet metal preform (2) can be produced in one or more steps by means of any combination of shaping processes. The preforming tool can thus be combined with the reference number (10) from one or more tools which are suitable for producing a sheet metal preform (2) from a sheet metal (1). The sheet metal (1) is unwound and cut to length from a metal bundle/coil, not shown, for example as a defined blank or blank, and made available for the further process. The metal sheet (1) is preferably made from a steel material, preferably from a high-strength steel material, for example with a material thickness of between 0.5 and 4 mm. Alternatively, aluminum materials or other metals can also be used.

In the 2 until 5 are in a schematic sectional view, and in the 3 and 4 additionally shown in the right representation in a schematic perspective representation is a partial section of a device in the longitudinal direction, a sequence of an embodiment of a method according to the invention or a device according to the invention, which at least relates to the configuration of the calibration tool (20). The method according to the invention for producing a sheet metal component (3), cf. 6 , thus comprises at least two steps. On the one hand, the method comprises preforming a metal sheet (1) into a sheet metal preform (2) having a base and two sides in cross section, each with a transition between the base and the side.

The sheet metal preform (2) or the sheet metal component (3) can, for example, comprise at least one section with a flange in the longitudinal extension (L), shown here on the left side of the downwardly open profile, and at least one section (2.1) without a flange. If at least one section is present, viewed in the longitudinal direction (L), with a flange, which can be arranged in different sections on one side or both sides, for example, there is also a transition between frame and flange in the area of the flange. The following explanations are shown using an example which shows a section in cross section in which both sides of the sheet metal preform (2) and, as a result, both sides of the sheet metal component are flangeless at least in one section. Of course, it is also possible for only one side to be flangeless and the other side to have a flange in cross-section, or to be completely flangeless (not shown).

The sheet metal preform (2) is produced in such a way that excess sheet metal material (4) is provided, which is preferably evenly distributed in the sheet metal preform (2) in the base or in the base and in the transition between base and frame(s). Additional excess sheet metal material can be introduced into the sheet metal preform (2), particularly locally, for example a further addition of material in each case near the two sheet metal preform ends, in the base as a base area (2.2) that bulges in the direction of the opening (Ö) of the sheet metal preform (2), in order to Sheet metal preform (2) to be positioned at least over the protruding bottom area (2.2) at least in the area of the flangeless section (2.1) of the sheet metal preform (2) on the calibration stamp (21) in such a way that the edge (2.11) present at least in the flangeless section (2.1) the sheet metal preform (2) is arranged above the stamp shoulder (21.1), cf. 2 .

Alternatively or additionally, the sheet metal preform (2) is provided with a base in which embossings (2.3) pointing locally or in sections in the direction of the opening (Ö), see the right-hand representation of the sheet metal preform (2) in 1 , have been produced during the preforming, so that the sheet metal preform (2) can be positioned at least via the stampings (2.3) on the calibrating die (21), cf. 3 that the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) is arranged above the stamp shoulder (21.1). The embossings (2.3) made in the base can be distributed in the longitudinal extension (L) along the base or else only as a local or sectional embossing (2.3) at the two ends of the sheet metal preform (2.3) viewed in the longitudinal direction (L). These also do not necessarily have to be introduced in the region of the flange-free section (2.1) of the sheet metal preform (2) if a sheet metal component is to be produced which is at least partially flanged. The introduced embossings (2.3) thus serve not only as spacers, but can also provide additional excess sheet metal material at least in the sections locally or in sections in the transverse extent of the sheet metal preform (2).

As a further alternative or in addition, at least one adjustable insert (21.2) can be arranged in the calibration stamp (21), cf. 4 , which can be spaced apart from the calibrating die (21), so that at least a partial area of the base comes into contact with the insert (21.2) when the sheet metal preform (2) is placed in the calibrating tool (20) and the sheet metal preform (2) at least over the partial area of the Bottom is positioned at least in the area of the flangeless section (2.1) of the sheet metal preform (2) on the insert (21.2) in such a way that the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) above the stamp shoulder (21.1) is arranged.

The sheet metal preform (2) is finished forming into a sheet metal component (3) in a calibrating tool (20) comprising at least one calibrating stamp (21) and at least one calibrating die (22), in which the relative movement between the calibrating stamp (21) and the calibrating die (22) excess sheet metal material (4) is compressed in the sheet metal preform (2), cf. 5 , left representation before UT, right representation in UT. It has been found to be advantageous that during the final forming the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) comes into contact with a stamp shoulder (21.1) of the calibrating stamp (21) as a result of the relative movement, is supported on it and is subjected to pressure in order to bring about the desired, at least local upsetting of the sheet metal preform, in particular during the further press stroke.

The configuration according to the invention makes it possible to ensure before the final forming or before the closing of the calibrating tool (20) that the sheet metal preform (2) can be positioned on the calibrating stamp without jamming and that flangeless sections (2.1) can also be dimensionally accurately finished in addition to optional flanged sections. For final forms of the exemplary in the 2 until 5 Not shown, flanged sections are provided in particular slides not shown to shut off the flange edges of the sheet metal preform in the calibration tool, so that these sections can experience a compressive stress overlay analogous to the flangeless sections (2.1).

After inserting the sheet metal preform (2) in the calibrating tool (20) or in such a way that the opening (Ö) of the sheet metal preform (2) points downwards and is positioned on the calibrating stamp (21), the calibrating die (22) during the relative movement, at least in the region of the flange-free section (2.1) of the sheet metal preform (2), with the smallest possible gap on the stamp shoulder (21.1) of the calibration stamp (21), before the final forming is completed or the compressive stress superimposition is initiated. Before the start of the upsetting/calibration process, it is thus ensured that at least the die cheek (22.1) of the calibration die (22) has passed the stamp shoulder (21.1) of the calibration stamp (21), so that uncontrolled flow during the compressive stress superimposition through the between the stamp shoulder (21.1 ) and edge (2.11), which could lead to jamming, is prevented. What is not shown is that the calibration die (22) can also be made in several parts, for example with at least one leading die cheek (22.1).

After completion of the final forming, the calibration tool (20) is opened again and the dimensionally stable sheet metal component (3) can be removed. The opened calibrating tool (20) is thus free again to be loaded again with a sheet metal preform (2) to be finished and formed.

At least one of the three aforementioned configurations is preferred, comprising a sheet metal preform (2) with a bulging base area (2.2), a sheet metal preform with local or sectional embossing (2.3) in the base and/or adjustable inserts (21.2) in the calibration die (21) when positioning the sheet metal preform (2) taken into account on the calibration stamp (21).

The invention is not limited to the embodiments shown. Other sheet metal part shapes are also possible and require appropriately adapted tooling, preforming and calibration tools. In particular, the tools (10, 20) can be designed as interchangeable tools and used in a production line, in particular in a press line, transfer press or progressive press.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was 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.

Patent Literature Cited

• DE 102007059251 A1 [0002]
• DE 102008037612 A1 [0002]
• DE 102009059197 A1 [0002]
• DE 102013103612 A1 [0002]
• DE 102013103751 A1 [0002]

Claims (10)

Method for producing a sheet metal component (3), the method comprising at least two steps: - Preforming a sheet metal (1) into a sheet metal preform (2) in a preforming tool (10), the sheet metal preform (2) being an open profile with an opening ( Ö) is formed and has in its longitudinal extension (L) at least one flangeless section (2.1) and at least regionally excess sheet metal material (4); and - final forming of the sheet metal preform (2) to form a sheet metal component (3) in a calibrating tool (20) comprising at least one calibrating stamp (21) and at least one calibrating die (22), in which the relative movement between the calibrating stamp (21) and the calibrating die (22) excess sheet material (4) is upset in the sheet metal preform (2); characterized in that the sheet metal preform (2) is placed in the calibrating tool (20) in such a way that its opening (Ö) points downwards and is positioned on the calibrating stamp (21), and that during the final forming the at least in the flangeless section (2.1 ) Existing edge (2.11) of the sheet metal preform (2) comes into contact with a stamp shoulder (21.1) of the calibration stamp (21) through relative movement, is supported on it and is subjected to pressure. procedure after claim 1 , wherein the calibrating die (22) is guided past the stamp shoulder (21.1) of the calibrating stamp (21) during the relative movement, at least in the area of the flangeless section (2.1) of the sheet metal preform (2) with the smallest possible gap, before the final forming is completed. Method according to one of the preceding claims, in which the sheet metal preform (2) is provided with a base which, in the course of the preforming, is subjected to excess sheet metal material (4) at least in the flange-free section (2.1) in such a way that a flow in the direction of the opening ( Ö) the bulging bottom area (2.2) has been produced during the preforming, so that the sheet metal preform (2) at least over the bulging bottom area (2.2) at least in the area of the flangeless section (2.1) of the sheet metal preform (2) on the calibration stamp (21) in such a way is positioned such that the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) is arranged above the stamp shoulder (21.1). Method according to one of the preceding claims, in which the sheet metal preform (2) is provided with a base in which embossings (2.3) pointing in the direction of the opening (Ö) have been produced locally or in sections during preforming, so that the sheet metal preform (2) is positioned at least via the stampings (2.3) on the calibration stamp (21) in such a way that the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) is arranged above the stamp shoulder (21.1). Method according to one of the preceding claims, in which the sheet metal preform (2) is provided with a base, at least a partial region of the base being provided with at least one adjustable insert ( 21.2), which is at a distance from the calibration stamp (21) when the sheet metal preform (2) is inserted, comes into contact and the sheet metal preform (2) at least over the partial area of the base, at least in the area of the flangeless section (2.1) of the sheet metal preform (2) on the Insert (21.2) is positioned in such a way that the edge (2.11) of the sheet metal preform (2) present at least in the flangeless section (2.1) is arranged above the stamp shoulder (21.1). Device for producing a sheet metal component (3), in particular for carrying out a method according to one of Claims 1 until 5 , with at least one preforming tool (10) for preforming a sheet metal (1) into a sheet metal preform (2), the sheet metal preform (2) being designed as an open profile with an opening (Ö) and in its longitudinal extension (L) at least one flangeless section (2.1) and has excess sheet metal material (4) at least in regions; and with at least one calibrating tool (20) for finish-forming the sheet metal preform (2) into a sheet metal component (3), the calibrating tool (20) comprising at least one calibrating stamp (21) and at least one calibrating die (22), the relative movement between the calibrating stamp ( 21) and calibrating die (22) the excess sheet metal material (4) in the sheet metal preform (2) is upset; characterized in that the sheet metal preform (2) can be positioned with its opening (Ö) downwards on the calibration stamp (21), the calibration stamp (21) having at least one stamp shoulder (21.1) which is located at least in the flangeless section (2.1) of the sheet metal preform (2) is provided, so that the edge (2.11) of the sheet metal preform (2), which is present at least in the flange-less section (2.1), can be brought into contact with a stamp shoulder (21.1) of the calibrating stamp (21) by the relative movement, can be supported on it and can be supported by a pressure can be applied. device after claim 6 , wherein the calibrating stamp (21) has at least one adjustable insert (21.2) which is arranged in the calibrating stamp (21) and can be spaced apart from the calibrating stamp (21). device after claim 6 or 7 , wherein the calibrating die (22) is made in several parts and has at least one adjustable die cheek (22.1) at least in the flangeless section (2.1) of the sheet metal preform (2). Device according to one of Claims 6 until 8th , wherein the stamping shoulder (21.1) has a maximum extension of the material thickness of the metal sheet (1) used plus >0 to 0.35 mm. Device according to one of Claims 6 until 9 , wherein the device is integrated in a press line, transfer press or progressive press.

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