EP3228402B1 - Method for producing a component having at least one overhang - Google Patents

Description

The invention relates to a method for producing a component having at least one projection according to the preamble of patent claim 1.

Such a method for producing a component having at least one protrusion from a flat material formed from a metallic material and having at least one wall thickness is already known, for example JP 55042157 A1 to be known as known. The method has a first step, in which the flat material is arranged between a first tool part and a second tool part arranged opposite the first tool part. In this case, the first tool part has at least one recess for producing the projection on a side facing the flat material. Furthermore, at least one of the tool parts has at least one flow barrier, which projects beyond a surface of the at least one tool part adjoining the flow barrier.

The method further comprises a second step, in which the flat material arranged between the tool parts is pressed by means of the tool parts, for example by pressing the tool parts against one another or towards each other, in particular pressed. The flow barrier is used to effect a desired flow of the metallic material, so that at least a part of the metallic material flows into the recess, whereby the projection is produced.

The US Pat. No. 7 516 772 B2 discloses a method for molding a product from a metal-based composite material.

In addition, the DE 31 01 123 C2 to take a known device for extruding a three-arm metal fork element from a cylindrical blank.

Object of the present invention is to develop a method of the type mentioned in such a way that particularly advantageous properties, in particular mechanical properties of the device can be realized.

This object is achieved by a method having the features of patent claim 1. Advantageous embodiments with expedient developments of the invention are specified in the remaining claims.

In the method according to the invention, a component having at least one projection is produced from a flat material which is formed from a metallic material and has at least one wall thickness. Under the sheet is to be understood that it has an at least substantially flat extent and is wider and longer than thick. In other words, the width and the width of the flat material running perpendicular to the width are substantially greater than the thickness of the flat material running perpendicular to the width and perpendicular to the length. Expressed in other words, the length and the width of the flat material, for example, span a plane, wherein the thickness extends at least substantially perpendicular to this plane. In the imaginary plane thus extend the length and the width of the flat material, wherein the length and the width are substantially greater than the thickness of the flat material, wherein the thickness is the aforementioned wall thickness of the sheet. The flat material thus has two opposite broad sides facing away from each other as well as obliquely or perpendicularly extending narrow sides, wherein the broad sides in the lying plane or at least substantially parallel to the plane.

The method comprises a first step, in which the flat material is arranged between a first tool part and a second tool part arranged opposite the first tool part. In this case, the first tool part on a side facing the flat material, in particular on one of the broad sides of the sheet-facing side, at least one recess for producing the projection. Furthermore, at least one of the tool parts has at least one flow barrier, which projects beyond at least one surface of the at least one tool part adjoining the flow barrier. The flow barrier is thus to be understood as meaning a survey which projects beyond the surface adjacent to the flow barrier and by means of which a desired flow of the metallic material of the flat material is selectively effected or avoided.

The method further comprises a second step, in which the flat material arranged between the tool parts is pressed by means of the tool parts. For this purpose, the tool parts, for example, pressed against each other or pressed against each other. In other words, for example, the tool parts are moved toward one another and pressed toward one another or toward one another, while the flat material is arranged between the tool parts and thereby supported at least indirectly, in particular directly, on the tool parts.

In order to produce the component in a particularly simple manner and to be able to realize particularly advantageous properties, in particular mechanical properties, of the component, it is provided according to the invention that the flat material is pressed in such a way by means of the tool parts that a part of the metallic material consists of a first portion, in which the projection is produced, and from at least one second partial region of the flat material adjoining the first partial region and arranged between the flow barrier and the recess during compression by means of the flow barrier, at a flow of the recess is prevented away and flows into the recess, whereby the projection is made.

In this case, the projection is produced such that the component after producing the projection in all wall regions whose distance from the projection is smaller than or equal to the extension of the projection, has a wall thickness which is greater than or equal to half the wall thickness of the sheet prior to manufacture the projection is. The extension of the projection is to be understood to mean the extent thereof from its free end to a wall region of the component which adjoins the projection directly. In other words, the projection merges at its other end opposite the free end into the wall region directly adjoining the projection, which is arranged, for example, in a plane to which the projection extends obliquely or vertically.

Characterized in that the particular finished device after producing the projection in all wall regions whose distance from the projection is smaller than or equal to the extension of the projection, has a wall thickness which is greater than or equal to half the wall thickness of the sheet before the production of the projection is, even after the production of the projection, the component has a sufficient or particularly high stability or strength, in particular with respect to bending load, so that the component can absorb and endure even high loads at least substantially without damage.

In other words, it is provided in the context of the inventive method that in all wall regions whose distance from the projection is less than or equal to the extension of the projection, caused by the production of the projection reduction of the wall thickness of the sheet to less than half the wall thickness , which has the flat material before producing the projection, is omitted. Thus, an excessive reduction in wall thickness of the flat material or the finished manufactured component is omitted, so that this has a particularly high strength or stability in its finished state and thus can endure high loads, without causing destruction or deformation of the device.

An excessive reduction in wall thickness of the flat material and thus an undesirably small wall thickness of the finished manufactured component can be avoided in particular by the fact that the projection not only of metallic material from the first portion, but also of metallic material from the adjoining the first portion, second Part area is produced. In the first partial region, the projection is produced or the projection is located in the finished manufactured state of the component exactly in the first partial region. In this case, the first portion is, for example, exactly in overlap with the recess, in which the metallic material flows, arranged.

By contrast, the second subarea adjoins or adjoins the first subarea, so that the second subarea, when producing the protrusion, is arranged without covering the recess, ie, not in overlap with the recess but, for example, next to the recess. For example, the second portion forms the immediately following the projection, aforementioned wall area. In the context of the method according to the invention thus the metallic material of the sheet flows not only from the first portion, but at least from the second portion in the recess, so that the material flowing into the recess, from which the projection is made, not only from the first Subarea, but also comes from the second subarea.

This means that, in particular by means of the flow barrier, a large-area flow of the metallic material of the sheet is effected, so that the projection can also be produced with a particularly large extent, while at the same time avoiding excessive wall thickness reduction of the sheet. The device produced by means of the method according to the invention is formed, for example, as a part, in particular hinge part, of a hinge and thus can support and endure even very high forces, which are transmitted for example by a door or flap on the hinge. At the same time, the component can be produced in a particularly simple and therefore time-consuming and cost-effective manner by means of the method according to the invention, since the component is not made of two separate parts which are connected to one another, in particular welded together, must, is produced, but the component can be made in one piece or as a one-piece component. Conventional such hinge parts are assembled, for example, from at least two parts. A first of these parts is a flat material, with a second of the parts forming the projection. The parts are provided, whereupon the projection is welded to the flat material. This time-consuming and costly procedure can be avoided by means of the method according to the invention, since the projection is made of the one-piece sheet material by a targeted flow of the metallic material of the sheet is effected in the recess.

The targeted flow of the metallic material is thereby effected at least by means of the flow barrier. By means of the flow barrier an undesired flow of the metallic material of the sheet is prevented or at least kept within limits, so that the metallic material does not or not excessively away from the recess but in the direction of the recess and into the recess flows. This targeted flow of the metallic material is thereby effected by means of the flow barrier and by the fact that the flat material is pressed by means of the tool parts. As a result, a material displacement, that is, a displacement of at least a portion of the metallic material causes. The displaced metallic material can - as an undesirable flow of the metallic material is prevented by the flow barrier or at least kept low - only or at least predominantly escape into the recess by the metallic material flows into the recess. As a result, the projection is produced, without resulting in excessive wall thickness reduction of the sheet material and thus the finished manufactured device.

However, since the projection is made of the metallic material of the flat material, the wall material is reduced in thickness so that the component or the flat material has a smaller wall thickness, at least in the second partial area, after the projection has been produced, than before the projection is produced. However, this wall thickness is greater than or equal to half the wall thickness that the sheet has prior to making the projection. By the requirement that the device after manufacturing of the device in all wall regions whose distance from the projection is less than or equal to the extension of the projection, has a wall thickness which is greater than or equal to half the wall thickness of the sheet before the production of the projection, can an excessive wall thickness reduction or an undesirably small wall thickness , which is arranged particularly close to the projection can be avoided.

In this case, the invention is based on the finding that, in particular in the case of the aforementioned hinge or when using the component as a hinge part, high forces or loads are usually introduced into the component via the projection. These forces or loads introduced via the projection of the component are usually distributed starting from the projection or the first partial region into other partial regions or wall regions of the finished manufactured component. If now an excessive wall thickness reduction, that is, for example, a wall thickness, which would be less than half the wall thickness of the sheet prior to making the projection after production of the projection, arranged particularly close to the projection, it could in the range of excessive wall thickness reduction to a Failure or come to a deformation of the device. These problems can be avoided by the method according to the invention, since an excessively close arrangement of wall regions whose respective wall thickness is less than half the wall thickness of the sheet material prior to the production of the projection can be avoided on the projection. As a result, the component has particularly advantageous properties, in particular particularly advantageous mechanical properties, so that the component can also support or bear high loads or forces without damage.

In a particularly advantageous embodiment of the invention, the other tool part arranged opposite the at least one tool part also has at least one second flow barrier on a side facing the flat material, which projects beyond a second surface of the other tool part adjoining the second flow barrier. As a result, the material of the sheet can be particularly effectively prevented from entering unwanted areas and for example, to flow away from the recess, so that a particularly advantageous and targeted flow of the metallic material can be realized. In particular, through the use of the second flow barrier, excessive wall thickness reductions of the flat material, in particular in all wall regions whose distance from the projection is less than or equal to the extension of the projection, can be avoided. As a consequence, particularly advantageous properties of the component can be represented.

In a further embodiment of the invention, the projection is made with a varying in the longitudinal direction of the projection cross-section. As a result, the cross section itself can be made stable, so that it is possible to realize particularly advantageous properties of the component. Further, it is conceivable that the projection is made with a constant in the longitudinal direction of the projection cross-section.

By the varying projection, it is to be understood, for example, that the projection in a first longitudinal region has a cross section with a first size and / or a first shape, the projection having a cross section with respect to the first one in a second longitudinal region different from the first longitudinal region Form having different second shape and / or compared to the first size of different, second size.

A further embodiment is characterized in that the extension of the projection produced by the pressing is greater than the wall thickness, which has the flat material before producing the projection, at least in the first portion in which the projection is produced. Characterized in that - as described above - the material for producing the projection not only from the first portion, but also originates from the second portion, the projection can be designed with a particularly large extent, which is greater than the wall thickness, which is the flat material at least in the first portion before the production of the projection. As a result, particularly advantageous properties of the component can be realized. In particular, it is possible to attach the component particularly advantageous to other components such as a door or flap of a household appliance.

In a further embodiment of the invention, the second portion is greater than the first portion. In this way, a particularly high amount of material of the sheet can be used to produce the projection, at the same time excessive wall thickness reductions of the sheet can be prevented. For example, at least in the second subregion, a wall thickness reduction of the flat material occurs, whereby this thinning reduction results from the production of the protrusion, however, excessive wall thickness reduction can be reliably avoided, in particular in the aforementioned wall regions. In this case, since the second partial area is larger than the first partial area, the projection can be produced with a particularly large extent, in particular with a particularly large thickness. As a result, a particularly high stability of the projection and thus of the component as a whole can be created.

It has proven particularly advantageous if the flow barrier, that is to say the first flow barrier and / or the second flow barrier, is pressed into the flat material. In this way, an undesirable flow of the metallic material can be kept particularly low or avoided, so that a targeted flow of the material can be effected in the projection.

It has proved to be particularly advantageous if a further recess of the component is produced by the press-fitting of the flow barrier. This means, for example, that the component after pressing the flow barrier in the flat material in the region of the recess has a smaller wall thickness than the flat material prior to pressing, wherein the recess is for example a different wall from a through hole, so that the device in the recess Has wall thickness and not about a through hole. In this embodiment, for example, a functional integration is created because not only the projection, but also the recess is made in the context of the method. As a result, particularly advantageous properties of the component can be adjusted as needed.

Another embodiment is characterized in that the component is machined after pressing in the region or along the further recess by punching. The further recess serves, for example, as a punching embossing or as a pre-embossing in order to be able to machine the component after the recess has been produced in a particularly simple and thus time-consuming and cost-effective manner by punching. As a result, the entire component can be made particularly time-consuming and cost-effective.

In order to effect a targeted flow of the metallic material, in particular into the recess, and to avoid unwanted flow of the metallic material, it is provided in a further embodiment of the invention that the flow barrier has a curved course. In other words, for example, a flow barrier with an at least partially curved course is used as the first flow barrier and / or as the second flow barrier.

In this case, it has proven to be particularly advantageous if the flow barrier has a first longitudinal region with a first curvature and a second longitudinal region adjoining the first longitudinal region, which has a second curvature that differs from the first curvature or runs straight. In other words, it can be provided that both length regions are curved and thus have a different course from a straight course, wherein, however, the length regions are curved to different degrees or have different curvatures. Alternatively, it is conceivable that one of the length regions is curved, wherein the other length region has an at least substantially straight course. As a result, it is particularly conceivable to be able to design the aforementioned further recess particularly advantageously with respect to its shape.

Finally, in order to realize a particularly simple and time and cost-effective production of the component, it is provided in a further embodiment of the invention that the projection is produced in a single stroke of the tool parts. In the context of the single stroke, for example, the tool parts are moved toward one another and pressed against one another and then moved apart, the projection having already been produced after moving apart, without the tool parts for producing the projection would have to be moved towards each other again.

The tool parts are moved toward one another, for example, by means of a press, in particular by means of an eccentric press, and pressed against one another or toward one another in order to press the flat material. For example, the tool parts are components of a punching tool, in particular a subsequent punching tool. In other words, the tool parts can be integrated into a stamping train. The punching tool is actuated, for example by means of the press or is used in such a press. The press is designed, for example, as an eccentric press or a hydraulic press or as another press.

The aforementioned punching can also take place in the press, in particular by means of the punching tool. Furthermore, it is conceivable to produce the projection by means of the press and to punch the flat material or the component in a punching tool, in particular in a subsequent punching tool, after producing the projection. In particular, it is possible that the projection is produced in a single stroke. By this stroke or by at least one subsequent further stroke, the flat material or the component can be punched, for example, in particular in the region of the further recess. In particular, it is possible in the context of the method according to the invention to produce the projection without heating the sheet. Thus, it is preferably provided that a targeted heating of the sheet material effected by means of a heating device is omitted. It has been found that the described, targeted flow of the metallic material can be effected without such additional heating of the sheet and only by the use of the at least one flow barrier and by the pressing of the sheet by means of the tool parts.

Furthermore, it has been shown that the component produced by means of the method according to the invention can be used particularly well as a fitting, chassis part, kinematics component or as a housing or housing component with integrated additional functions. In particular, that can Component be used as a functional part in the automotive sector. The metallic material is preferably a steel. Furthermore, it is conceivable that the metallic material is a light metal such as aluminum or a light metal alloy such as an aluminum alloy. Furthermore, it is possible that the metallic material from which the flat material is formed is stainless steel.

In simplified terms, the metallic material is at least partially enclosed in the process by means of the flow barrier, so that a desired contour in the form of the projection of the component is expelled by means of the flow barrier. As a result, the protrusion in the first subregion can be produced without a stamp or the like protrusion having to be pressed or driven into the flat material on the side facing away from the protrusion in the first subregion. The projection can thus be made by effecting said flow of said material, whereby excessive wall thickness reductions can be safely avoided. In this case, a weakening of the rear side facing away from the back can be avoided as well as a punctiform depression on the back. Furthermore, it is possible to design the extension of the projection formed, for example, as an embossing height to be larger than the material thickness, that is to say the wall thickness of the flat material in the first partial region prior to the production of the projection. Overall, a particularly high stability and strength of the device can be created by the inventive method and by the one-piece design of the device, that is the projection with the adjoining wall area.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawing. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures are not only in the respectively indicated combination, but also in others Combinations or alone, without departing from the scope of the invention.

Fig. 1

eine schematische Perspektivansicht eines wenigstens einen Vorsprung aufweisenden Bauelements in einem noch nicht fertig hergestellten Zustand;

Fig. 2

ausschnittsweise eine schematische Seitenansicht des Bauelements;

Fig. 3

eine schematische Perspektivansicht eines Flachmaterials, aus welchem das Bauelement hergestellt wird;

Fig. 4

ausschnittsweise eine schematische Schnittansicht zweier Werkzeugteile, mittels welchen das Bauelement aus dem zwischen den Werkzeugteilen angeordneten Flachmaterial hergestellt wird;

Fig. 5

ausschnittsweise eine schematische Perspektivansicht eines die Werkzeugteile umfassenden Werkzeugs zum Herstellen des Bauelements;

Fig. 6

ausschnittsweise eine weitere schematische Perspektivansicht der Werkzeugteile;

Fig. 7

ausschnittsweise eine weitere schematische Perspektivansicht der Werkzeugteile; und

Fig. 8

ausschnittsweise eine schematische Perspektivansicht eines der Werkzeugteile.

The drawing shows in:

Fig. 1

a schematic perspective view of a at least one projection having component in a not yet finished state;

Fig. 2

partially a schematic side view of the device;

Fig. 3

a schematic perspective view of a sheet material from which the device is manufactured;

Fig. 4

a section of a schematic sectional view of two tool parts, by means of which the component is made of the arranged between the tool parts flat material;

Fig. 5

1 is a schematic perspective view of a tool comprising the tool parts for producing the component;

Fig. 6

a detail of another schematic perspective view of the tool parts;

Fig. 7

a detail of another schematic perspective view of the tool parts; and

Fig. 8

a schematic perspective view of one of the tool parts.

In the figures, the same or functionally identical elements are provided with the same reference numerals.

Fig. 1 shows in a schematic perspective view of a generally designated 10 component in a state in which the device is not yet completely made. In the in Fig. 1 illustrated state, the device 10, for example, a semi-finished, which is further processed to finally produce the device 10 from the semifinished product. The in Fig. 1 shown state of the device 10 may be an intermediate state or an intermediate stage, the component occupies, for example, in a progressive tool, in particular between two tools of the progressive tool.

As will be explained in more detail below, the device 10 is made of a in Fig. 3 produced flat material 12, wherein the flat material 12 is formed of a metallic material and has at least one wall thickness t. In the present case, the wall thickness t is at least substantially constant and provided in all wall regions of the flat material 12. The metallic material is, for example, a steel or a light metal such as aluminum. Furthermore, the metallic material may be a stainless steel.

Especially good Fig. 1 and 2 It can be seen that the component 10 has a projection 14, which in the present case is designed as a pin or pin element and can be used, for example, as a pin to the component 10 via the projection 14 with at least one further, not shown in the figure, in particular component articulated, to connect. For example, the component 10 is used as part of a hinge, wherein the component 10 is connected in the fully manufactured state of the hinge via the example formed as a pivot pin projection 14 hingedly connected to another part of the hinge. In particular, the component 10 can be connected via the projection 14 in an articulated manner to a door or a flap of a device, in particular a domestic appliance.

Out Fig. 3 It can be seen that the flat material 12 is to be understood as meaning that the flat material 12 has a width B and a length L which is substantially greater than the wall thickness t, which is also referred to as the thickness. The width B and the tension Length L is an imaginary plane to which the wall thickness t or its extension is perpendicular. In the present case, the flat material 12 is at least substantially parallelepiped-shaped and accordingly has six sides 16a-f, the sides 16a and 16b being broad sides and the sides 16c-f being narrow sides of the flat material 12. In this case, the sides 16a and 16b are arranged opposite one another or away from each other and extend, for example, at least substantially parallel to the said plane.

A method for producing the component 10, which is produced from the flat material 12 in the context of the method, will be described below. It shows Fig. 5 a detail of a designated overall by 18 tool, by means of which the component 10 is made of the flat material 12. For this purpose, the tool 18 comprises tool parts 20 and 22, which are arranged opposite each other in the context of the method.

In synopsis with Fig. 4 It can be seen that for producing the component 10, the flat material 12 is initially arranged between the tool parts 20 and 22. In this case, for example, the side 16a faces the tool part 22, while the side 16b faces the tool part 20. The tool part 22 has at least one recess 24, by means of which the projection 14 is produced. Furthermore, the tool parts 20 and 22 - as in conjunction with Fig. 6 to 8 recognizable-respective Fließbarrieren 26 and 28 on. In the context of the method, and in particular during the production of the projection 14, the flow barrier 28 of the tool part 22 is arranged, for example, opposite the flow barrier 28 of the tool part 20, whereby the flow barrier 26 of the tool part 22 is arranged opposite the flow barrier 26 of the tool part 20.

The respective flow barrier 26 or 28 projects beyond a respective surface 30, 32 or 34 of the respective tool part 20 or 22 adjoining the respective flow barrier 26 or 28, respectively Fig. 5 It can be seen here that the flow barrier 28 surrounds the surfaces 30 and 32 completely circumferentially, so that the surfaces 30 and 32 are arranged within the flow barrier 28 and the surface 34 outside the flow barrier 28. In this case, the surface 32 projects beyond the surface 30 or the surface 32 is opposite the surface 30 raised. Furthermore, the flow barrier 28 also completely surrounds or surrounds the flow barrier 26, so that the flow barrier 26 is also arranged within the flow barrier 28. In this case, the flow barrier 26 is raised relative to the surfaces 30 and 32.

In the method, arranged between the tool parts 20 and 22 flat material 12 is pressed by means of the tool parts 20 and 22. For this purpose, the tool parts 20 and 22 are driven toward each other, for example, as in Fig. 5 is illustrated by arrows 36. Furthermore, the tool parts 20 and 22 are pressed or pressed against each other or towards each other, so that the flat material 12 is pressed by means of the tool parts 20 and 22. During the pressing of the flat material 12, the flow barrier 28 of the tool part 22 is arranged opposite the flow barrier 28 of the tool part 20. Furthermore, the flow barrier 26 of the tool part 22 is arranged opposite the flow barrier 26 of the tool part 20. Furthermore, the surface 30 of the tool part 22 is arranged opposite to the surface 30 of the tool part 20, and the surface 32 of the tool part 22 is arranged opposite to the surface 32 of the tool part 20. Due to the described size ratios of the flow barriers 26 and 28 and the surfaces 30 and 32, a first gap, which is formed during the compression of the sheet 12 by the surface 32 of the tool part 22 and the surface 32 of the tool part 20, narrower than a second gap, which is bounded by the surface 30 of the tool part 22 and the surface 30 of the tool part 20 during the pressing of the sheet 12. Further, a third gap formed by the flow barrier 26 of the tool part 22 and the flow barrier 26 of the tool part 20 during compression of the sheet 12 is narrower than the second gap. It is provided in the context of the embodiment illustrated in the figures that the flow barriers 26 and 28 pressed into the sheet 12, in particular embossed, are.

As part of the process, the flat material 12 is pressed such that a portion of the metallic material of the sheet 12 from a first portion 38 in which the projection 14 is made, and at least one adjacent to the first portion 38 and during compression between the flow barriers 26 and 28 and the recess 24 arranged second portion 40 of the sheet 12 is prevented by means of the flow barriers 26 and 28 at a flow away from the recess 24 and flows into the recess 24, whereby the projection 14 is produced. In this case, the projection 14 is produced such that the component 10 after producing the projection 14 in all wall regions whose distance from the projection 14 is less than or equal to the particularly good in Fig. 2 apparent extent s of the projection 14, has a wall thickness t2 which is greater than or equal to half the wall thickness t of the sheet material 12 prior to the production of the projection 14. The wall regions described above, whose distance from the projection 14 is less than or equal to the extension s of the projection 14, are hereinafter also referred to as Wanddickenwandungsbereiche sake of simplicity and conceptual delimitation. Under these Wanddickenwandungsbereiche wall areas in the true sense, ie those wall areas to understand in which metallic material of the sheet 12 and the component 10 is present. The Wanddickenwandungsbereiche are thus of a through hole different wall areas in which no through hole is made and in which consequently still metallic material of the sheet 12 is present.

Characterized in that in all Wanddickenwandungsbereichen the wall thickness t2 is provided, which is greater than or equal to half the wall thickness t, but less than the wall thickness t, excessive, caused by the production of the projection 14 wall thickness reductions and thus excessive weakening of the sheet 12 and Component 10 can be avoided so that the device 10 even after or despite the production of the projection 14 particularly advantageous properties, in particular mechanical properties. In other words, the component 10 still has a sufficient wall thickness even after the production of the projection 14, so that a particularly advantageous strength or stability of the component 10 can be realized. As a result, particularly high forces or loads can be introduced into the component 10, for example, via the projection 14, without any failure or deformation of the component 10 occurring.

In Fig. 4 is shown by dashed lines the original sheet 12. By means of the dashed lines, it can be seen particularly clearly that, for example, in the subregions 38 and 40 a wall thickness reduction occurs, so that the wall thickness t2 is less than the wall thickness t, but the wall thickness t2 is greater than or equal to half the wall thickness t, so Particularly advantageous properties of the device 10 can be realized. Furthermore, it can be seen that metallic material of the flat material 12 not only flows out of the first subregion 38, but in particular also out of the second subregion 40 into the recess 24 as a result of the compression of the flat material 12, thereby producing the protrusion 14. This results in a reduction in the wall thickness of the flat material 12 in comparison to the wall thickness t both in the partial area 38 and in the partial area 40, but this wall thickness reduction remains low, since the material from which the projection 14 is made not only from the partial area 38, but also comes from the section 40. Furthermore, by means of the flow barriers 26 and 28, an undesirable flow of the metallic material of the flat material 12 away from the recess 24 can be avoided or at least minimized so that metallic material flows selectively into the recess 24 both from the partial area 38 and from the partial area 40. Thereby, it is possible that the extension s of the projection 14 is greater than the original wall thickness t, wherein the resulting wall thickness t2 is still greater than or equal to half the original wall thickness t.

How out Fig. 2 is particularly well recognizable, extends the extension s of the projection 14 of the free end 42, for example, at least substantially perpendicular to the aforementioned imaginary plane to a directly adjoining the projection 14 wall portion 44 of the device 10, said wall portion 44, for example, in said , imaginary plane is arranged and thus at least substantially perpendicular to the extension direction, in particular to the longitudinal extension direction, of the projection 14 extends. For example, the wall portion 44 is formed by the second portion 40.

Especially good Fig. 4 It can be seen that the second portion 40 is formed larger than the first portion 38, so that a particularly large amount of metallic material of the sheet 12 can be used to the Lead projection 14. As a result, a particularly large extent s of the projection 14 can be realized, wherein at the same time an excessive wall thickness reduction of the component 10 can be reliably avoided.

Especially good Fig. 1 It can be seen that respective recesses 46 and 48 of the flat material 12 or of the component 10 are produced by press-fitting the respective flow barrier 26 or 28 into the flat material 12. In this case, the recess 46 is produced by means of the flow barrier 26, wherein the recess 48 is produced by means of the flow barrier 28. It can be provided that the component 10 is punched along or in the region of the recess 48, thereby separating the component 10 from the rest of the flat material 12. The recess 48 can thus represent a possible contour, in particular end contour, of the component 10, so that the component 10 is punched out along this end contour and finally, in particular on the outer peripheral side, has the final contour.

If the component 10, in particular after the pressing of the flat material 12, is processed by punching along the further recess 46, a passage opening of the component 10 is produced, for example in the region of the recess 46, wherein this passage opening no longer belongs to the aforementioned wall thickness wall regions, since then no wall thickness or no material of the flat material 12 is present in the region of the passage opening. The passage opening produced by punching can then act, for example, as a guide curve or guide track or guide track along which, for example, at least one further component, in particular a further part of the hinge, can be guided, when the further part is moved relative to the component 10. By making the recess 46, the component 10 can thus be pre-stamped in order to produce the guide slot particularly time-consuming and cost-effective. Overall, the device 10 can be made particularly time-consuming and inexpensive, since the device 10 is integrally formed. This means that the projection 14 or the component 10 having the projection 14 is produced from the one-piece flat material 12, so that additional joining operations, in the context of which two parts formed separately from one another are connected to one another, in particular welded together, are not provided and are not required. In particular, it is not provided and is not necessary to connect, in particular to weld, a first part forming the projection 14 with a second part formed thereon, which is designed, for example, as a flat material, because the component 10 may be formed integrally from the one-piece flat material 12 the manner described are produced by the flat material 12 is pressed by means of the tool parts 20 and 22.

Especially good Fig. 6 It can be seen that the surface 32 is arranged at least partially, in particular at least predominantly, between a first longitudinal region of the flow barrier 28 and the flow barrier 26. In particular, it is possible that the device 10 in the in Fig. 1 illustrated state in which the device 10 is not yet processed by punching along the recesses 46 and 48, also in the areas of the recesses 46 and 48 has the wall thickness t2 or a further wall thickness which is greater than or equal to half the wall thickness t, having.

Another advantage of the procedure is that - how very good Fig. 4 is recognizable - in comparison to impressed contours no notch effect arises. Furthermore, a material compression can be effected, so that the component 10 has particularly good properties. In addition, the surface of the formed, for example, as an embossed element component 10 remains at least substantially smooth.

By means of the flow barriers 26 and 28, the metallic material is enclosed or held in order to realize a targeted flow of the metallic material. In this case, by pressing the flat material 12, an at least substantially flat pressure is exerted on the flat material 12 both from the side of the tool part 20 and from the side of the tool part 22, in order to specifically effect the described flow of the metallic material into the recess 24. By means of the method, it is also possible to produce particularly complex components in a progressive composite, it being readily possible to produce such components from a coil. The method is thus particularly advantageous for realizing a time-consuming and cost-effective mass production. Especially It is possible to produce or produce the component 10 in a single stroke, wherein a targeted, caused by a heater heating of the sheet 12 can be omitted.

The tool 18 is actuated, for example, by means of a press, wherein the tool parts 20 and 22 are moved toward one another by means of the press and pressed against one another or towards one another. The tool 18, in particular the tool parts 20 and 22, can be integrated into a punching tool, in particular into a subsequent punching tool, in order to machine the component 10 by punching by means of the punching die casting. The punching tool is used, for example, in the press. Thus, both the production of the projection 14 and the described punching machining of the component 10 or of the flat material 12 can be carried out in a simple, time-saving and cost-effective manner, in particular by means of the eccentric press.

Claims (11)

1. Method for producing a component (10) having at least one projection (14) from a flat material (12) formed of a metallic substance and having at least one wall thickness (t), including the steps of:

   - arranging the flat material (12) between a first tool part (20) and a second tool part (22) arranged opposing the first tool part (20), wherein the first tool part (20) has at least one recess (24) for producing the projection (14) on a side facing the flat material (12), and wherein at least one of the tool parts (20, 22) has at least one flow barrier (26, 28), which protrudes beyond a surface (30, 32, 34) of the at least one tool part (20, 22) adjoining to the flow barrier (26, 28), and

   - pressing the flat material (12) arranged between the tool parts (20, 22) by means of the tool parts (20, 22),

   characterized in that
   the flat material (12) is pressed such that a part of the metallic substance is prevented from flowing away from the recess (24) from a first partial area (38), in which the projection (14) is produced, and from at least one second partial area (40) of the flat material (12) adjoining to the first partial area (38) and arranged between the flow barrier (26, 28) and the recess (24) in pressing by means of the flow barrier (26, 28) and flows into the recess (24), whereby the projection (14) is produced such that the component (10) has a wall thickness (t2) in all of the wall areas, the distance of which to the projection (14) is less than or equal to the extension (s) of the projection (14) after producing the projection (14), which is greater than or equal to half of the wall thickness (t) of the flat material (12) before production of the projection (14).
2. Method according to claim 1,
   characterized in that
   the other tool part (22) arranged opposing the at least one tool part (20) also has at least one second flow barrier (26, 28) on the side facing the flat material (12), which protrudes beyond a second surface (30, 32, 34) of the other tool part (20, 22) adjoining to the second flow barrier (26, 28).
3. Method according to claim 1 or 2,
   characterized in that
   the projection (14) is produced with a cross-section varying or constant in longitudinal extension direction of the projection (14).
4. Method according to any one of the preceding claims,
   characterized in that
   the extension (s) of the projection (14) produced by pressing is greater than the wall thickness (t), which the flat material has at least in the first partial area (38), in which the projection (14) is produced, before producing the projection (14).
5. Method according to any one of the preceding claims,
   characterized in that
   the second partial area (40) is larger than the first partial area (38).
6. Method according to any one of the preceding claims,
   characterized in that
   the flow barrier (26, 28) is pressed into the flat material.
7. Method according to claim 6,
   characterized in that
   at least one further recess (46, 48) of the component (10) is produced by pressing the flow barrier (26, 28).
8. Method according to claim 7,
   characterized in that
   the component (10) is processed by punching in the area of the further recess (46, 48) after pressing.
9. Method according to any one of the preceding claims,
   characterized in that
   the flow barrier (26, 28) has an arcuate progression.
10. Method according to any one of the preceding claims,
    characterized in that
    the flow barrier (26, 28) has a first length area with a first curvature and a second length area adjoining to the first length area, which has a second curvature different from the first curvature or extends straight.
11. Method according to any one of the preceding claims,
    characterized in that
    the projection (14) is produced in a single stroke of the tool parts (20, 22).

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