DE102011052773A1 - Tool useful for a press hardening tool, comprises a molding surface, where a blank is present for the purpose of transformation, and is microstructured partially by micro depressions introduced in molding surface - Google Patents

Abstract

Tool (1) for a press hardening tool, comprises a molding surface (2), where a blank is present for the purpose of transformation. The molding surface of the tool is microstructured at least partially by micro depressions (3) introduced in the molding surface, and so the effective contact surface between the molding surface having the blank on the surface portions located between the depressions is limited for the transformation of the blank.

Description

The invention relates to a tool for a press-hardening tool having a shaping surface on which a blank rests for the purpose of its forming.

Press hardening tools are tools with which metal blanks are formed and hardened. For the purposes of hardening, depending on the configuration of the method, a correspondingly preheated blank is fed to the press-hardening tool, formed therein and cooled sufficiently rapidly during the shaping to harden it. Such press-hardening tools are used, for example, for producing structural components of motor vehicles. The blanks are usually sheet steel blanks.

The forming rates of the boards to be reshaped by such a press-hardening tool are sometimes considerable. In addition, the formed blanks may have narrow radii. For the purpose of corrosion protection, the steel plates to be subjected to the forming process are coated with a metallic anticorrosive coating, for example galvanized or coated with zinc / nickel or with zinc / aluminum, thus carrying a coating which, together with the steel plate, is subjected to the forming and hardening process. When using such corrosion-protected boards, however, has shown that they can be formed only with a limited degree of deformation without the zinc coating is damaged. In particular, in such a coated steel sheet microcracks occur in the metallic corrosion protection coating which can pass through the entire corrosion protection layer and also extend into the base material. As a result, the function of the component can be impaired under certain conditions. The use of galvanized blanks as blanks is preferred over a corrosion protection coating of the press-hardened semifinished product.

Based on this discussed prior art, the invention is therefore the object of developing an aforementioned tool in such a way that with this zinc-coated steel blanks can be formed as blanks with higher forming rates and with relatively narrow radii or press-hardened. The micro-cracks mainly occur in those areas where tensile and compressive stresses overlap during forming.

This object is achieved according to the invention by an aforementioned generic tool in which the shaping surface of the tool is microstructured at least partially by introduced into the mold surface microwells and thereby effective for the forming of a blank contact surface between the mold surface with a blank on the between the Wells located surface portions is limited.

This tool has at least partially on a microstructured surface. In any case, if the entire mold surface of the tool does not have such a microstructure, the microstructured regions will be in those mold surface areas against which the portions of the blank typically subjected to zinc coating damage will rest. The microstructuring is achieved by introduced into the mold surface microwells. The microstructuring is typically carried out in such a way that the surface structure of the blank is not different or at least not visually perceptible from that surface which is achieved with a conventional tool without such a microstructuring. By this measure, the effective contact surface between the mold surface and a blank is limited to the high relative to the wells areas in this tool. Thus, the effective contact area of the microstructured mold surface with the blank is reduced relative to the area of the microstructured mold surface area. As a result of the reduced contact area, the friction acting on the surface of the blank adjacent thereto is accordingly correspondingly lower. It is believed that this is the benefits achieved with the tool benefits. It was surprisingly found that with such a mold surface, zinc coated steel blanks could also be subjected to a press hardening process, which could produce considerable forming rates and narrow radius workpieces without the zinc coating exhibiting unacceptable damage.

The microstructuring of the mold surface or molding surface (s) is typically accomplished by a microforge process, such as by a knocking process. An advantage of such a process is that not only the microwells can be introduced as such in the tool surface, but at the same time sets by this process a work hardening and thus an additional hardening of the treated in this respect form surface area. The knocking process is particularly good with the in WO 2007/016919 A1 perform method described, but in contrast to the spherical knocking tool described in this prior art, a pointed knocking tool is used. Through this explicit reference WO 2007/016919 A1, the knocking method described therein is made to the disclosure of these statements.

Such a tapping tool provided with a tip can be embodied as a cone tip, pyramid tip or the like. Preferred is an embodiment in which the tapping body and accordingly the micro-recesses created therewith have equilateral peripheral surfaces, thus, for example, are designed square or in the manner of a rhombus. Also, the formation of wells with more than four pages is possible. The design of recesses with straight side surfaces has the consequence that the remaining between the wells webs as high areas have a constant web width. As a result, the effective contact area between two recesses over the extent thereof and thus the friction between these sections and the blank to be formed is the same.

The depressions are typically carried out in the manner of a geometric grid, at least largely approximated to such a grid. Depending on the design of the grid and thus the size of the recesses in the diameter and the distance of the recesses from each other, the effective contact surface of the microstructured or the surface areas of the mold surface can be adjusted. It is understood that even small reductions in the effective contact surface lead to a reduction in friction and thus to the possibility of reshaping, for example, zinc-coated steel blanks with larger forming rates. On the other hand, it will be understood that the ridges remaining between the recesses, the top of which is the effective mold surface, can not be reduced to an absolute minimum, since then the mold surface would no longer have the necessary tool stability. It has been found that with a reduction in the effective contact area of the microstructured molding surface area (s) to 70%, semifinished products can be produced with the desired forming rates and desired, even tight radii without the zinc coating undergoing corrosion inhibiting changes. A contact surface which corresponds to 60% to 65% of the microstructured molding surface area is considered particularly expedient. In the case where the forming process is performed with a lubricant support, the microstructured mold surface areas need only have an effective contact area of 80% to 85% of the microstructured mold surface area.

Further advantages of the embodiment of the invention will become apparent from the following description of an embodiment with reference to the accompanying drawings in which:

1 : A schematic side view of a tool as part of a press-hardening tool,

2 a greatly enlarged plan view of a section of the mold surface of the tool 1 and

3 FIG. 4: a section through the section of the mold surface along the line A-B of FIG 2 ,

A tool 1 is part of a press-hardening tool, which is otherwise not shown in more detail, provided for example for producing a motor vehicle structural component. With the press hardening tool, a blank, in the present case a galvanized sheet steel blank is formed and hardened in one operation. That in 1 tool shown has a mold surface 2 which has a simple geometry in the illustrated embodiment. With the tool 1 can be attached to the mold surface 2 Produce U-shaped support with a complementary counter-tool, not shown, made of flat sheet steel blanks as Rohlungen.

Of special feature with the tool 1 is the conception of his form surface 2 , This is microstructured by means of a micro-forging process, namely, as is 2 in a greatly enlarged plan view of the mold surface 2 of the tool 1 can be seen by introducing square or diamond-shaped microwells 3 , The wells 3 are from each other, leaving each a bridge 4 evenly spaced. The wells 3 are arranged in the manner of a grid to each other. In the illustrated embodiment, the recesses 3 with a corner in the expected direction of movement of one on the mold surface 2 to be formed blank. The microwells 3 of the illustrated embodiment have a diameter of about 5 m.

3 shows in a cross section the section of the mold surface 2 with the microwells incorporated therein 3 and those between the microwells 3 located bridges 4 , The top of the footbridges 4 represents the high areas and forms the original form surface 2 off before in this the microwells 3 have been introduced.

In the illustrated embodiment, the entire mold surface 2 of the tool 1 microstructured in the manner described. It is understood that it is sufficient in principle, only those areas or sections of the Mold surface of such a tool to be provided with such a microstructure, where a special friction between the mold surface 2 and the surface of one by means of the tool 1 is to be formed blank to be formed.

In the illustrated embodiment, the through the wells 3 introduced microstructuring by means of a knocking process in the original mold surface of the tool 1 been introduced. This has been used for this purpose WO 2007/016919 A1 described method using a pyramidal knocking tool.

When using the tool 1 the blank is only at the through the webs 4 formed high areas of the mold surface 2 at. Due to the dimensioning of the wells 3 becomes during the pressing and forming process of the blank 3 not in the wells 3 pressed. Rather, the surface of the remains with the tool 1 press-hardening blank - in particular a galvanized sheet steel plate - at least visually unchanged. From the top view of a on a greatly enlarged section of the mold surface 2 in 2 it becomes clear that as a result of the microwells 3 through the top of the webs 4 effective contact surface covering the mold surface 2 and at which a blank is applied to its deformation or applied, with respect to the actual surface of the mold surface 2 is not significantly reduced.

The microwells 3 of the illustrated embodiment are provided in the manner of a grid and therefore in a regular arrangement. It is understood that the same advantages can also be achieved with a tool in which the microwells have an irregular distribution on the microstructured surface of the tool.

With the tool 1 as part of a press-hardening tool can due to the microstructuring of its mold surface 2 the automotive structural components to be produced therefrom are made of galvanized sheet steel blanks, wherein in the course of the press hardening process, the zinc coating undergoes - if at all - no longer tolerable damage.

In an embodiment, not shown in the figures, it is provided to introduce a lubricant into the microwells, by means of which the friction between the mold surface and the blank to be formed is further reduced. In this embodiment, the microwells serve 3 thus on the one hand to reduce the effective contact surface with respect to the original surface of the mold surface and on the other hand as a depot for a lubricant. In this embodiment, it is therefore not absolutely necessary to additionally introduce a lubricant in the press hardening process, should this be desired. The invention has been described with reference to an embodiment. For a person skilled in the art, the disclosure content of this description gives rise to further possibilities for realizing the invention to the extent that it is valid, without this having to be described in detail in detail.

LIST OF REFERENCE NUMBERS

1

Tool

2

mold surface

3

deepening

4

web

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• WO 2007/016919 A1 [0007, 0018]

Claims (8)

Tool for a press-hardening tool with a shaping surface ( 2 ), on which a blank for the purpose of its forming, characterized in that the forming surface ( 2 ) of the tool ( 1 ) at least partially into the mold surface ( 2 ) introduced microwells ( 3 ) is microstructured and thereby the effective for forming a blank contact surface between the mold surface ( 2 ) with a blank on the between the wells ( 3 ) ( 4 ) is limited. Tool according to claim 1, characterized in that the microwells ( 3 ) are arranged in the manner of a grid to each other. Tool according to claim 1 or 2, characterized in that the depressions ( 3 ) have an angular, in particular equilateral outline geometry, for example, a diamond-shaped outline geometry. Tool according to one of claims 1 to 3, characterized in that the effective contact surface of the mold surface ( 2 ) is less than 70 percent of the microstructured area. Tool according to one of claims 1 to 4, characterized in that only certain mold surface areas of the tool are microstructured. Tool according to one of claims 1 to 5, characterized in that the or the microstructured mold surface areas of the tool are created by a micro-forging method, in particular by means of a knocking process. Tool according to one of claims 1 to 6, characterized in that the microwells are applied in the manner of an irregularly shaped arrangement and surface texture. Tool according to one of claims 1 to 7, characterized in that solid and / or liquid lubricant additives are knocked into the microwells.

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