DE102015118606A1 - Forming tool and method for its production - Google Patents

Abstract

The invention relates to a tool for forming metal sheets, in particular for deep drawing steel sheet, wherein a rough contour of a workpiece 6 to be formed with a plurality of plates 4, columns 9 or blocks is formed and on the workpiece 6 facing surface, of the Plates 4, columns 9 or blocks is formed, a mass 2 is printed, which fills the rough contour and the workpiece side forms a shaping surface 7, and a method for producing such a tool.

Description

The invention relates to a forming tool and a method for its production.

For forming and in particular for deep drawing of metals, it is known to insert these metals as sinkers in a tool, clamp these boards edge side and then press with a male in a die to give the metal the shape. By clamping the edges on the one hand and the pressure of the male on the other hand, the metal flows and is accordingly drawn into the die and there completely applied by the male to the die.

In addition, in prototype construction, it is still possible to produce shapes from wood or plastics and then to adapt the metals to the shape by means of hammering.

Such forming tools are milled, for example, from solid metal plates. The milling of solid metal plates on the one hand goes fast, but the milling is quite expensive and it is often produced a large amount of milling scrap.

In addition, it is known to produce forming tools from metallic raw casting, wherein the raw casting is already adapted to the final shape of the desired component, in which case the raw casting is still over-milled to ensure the fine machining of the surface. This has the disadvantage that the raw casting has a relatively long-consuming production and thus also requires a long production time. However, compared to the milling costs are lower and it is only to a lesser extent expected with Fräsverschnitt.

Basically, the tools for the forming of metals and in particular z. B. for the deep drawing of body panels have a high mechanical stability and good stability, because with such tools very high numbers of formed sheets are produced.

The object of the invention is to reduce the use of materials, the machining insert and possible waste and shorten the production time.

The object is achieved with a tool having the features of claim 1.

Advantageous developments are characterized in the subclaims.

Another object of the invention is to provide a method of manufacturing a forming tool.

This object is achieved by a method for producing such a tool having the features of claim 9.

According to the invention, material for tools is used only where it is necessary. Where it is not necessary for reasons of stability, material can be replaced by cavities.

In addition, according to the invention, the active surfaces and the actual component geometry are not cast and milled but produced by 3D printing.

The surface created by 3D printing is printed on a metallic substructure or a UREOL or HWS block material.

UREOL is a polyurethane resin filled with fillers and can be used to make deep-drawing molds, as well as injection molds when filled with metals, but has a very short life.

HWS is a comparable material, which is also offered in blocks and made of plastic.

According to the invention, this material is used in particular in the form of blocks, but also metal plates can be used. The metal plates or blocks can be cut by laser or water jet cutting or, in the case of plastics, also by conventional cutting methods. The cutting preferably results in blocks having the same width and a same thickness, but with a different height, wherein the height depends on the desired contour of a tool surface and thus ultimately on a desired contour of a formed component.

The blocks or plates are then arranged with their broad side surfaces together and so assembled with multiple blocks to a tool contour, wherein the tool contour of the surface contour of a desired component is approximated.

According to the invention, this rough tool contour is formed such that at least 85%, preferably more than 90%, particularly preferably more than 95%, of the volume of the entire tool is already formed.

On a component assigning, in particular stepped by the blocks trained surface can then be printed by 3D printing, the actual shaping surface. This then corresponds to the remaining <5% to <15% of the tool volume.

The tool volume is the volume below the workpiece side surface of the tool.

The shaping surface is printed in particular with metals known per se, wherein the metals are subsequently sintered, for example by means of laser sintering.

According to the invention thus provides the sintered metal surface as a shaping surface for the good surface quality and long life, while the underlying metal or plastic blocks absorb the required surface load.

In particular, it is useful in the invention, for a given workpiece length and width, a plurality of plate-like elements having the required width or length, with broad side surfaces to each other until the required other spatial dimension (width, length) is reached.

These plates can then be held together with suitable mechanical fasteners.

These mechanical fasteners may be through the plates pushed through bolts, but also tongue and groove guides or dovetail guides in the plate surfaces, with corresponding grooves and springs or dovetail guides adjacent plates interact.

Accordingly, in order to follow as closely as possible a planned contour of a component, the surfaces of the plates, which together form the shaping surface, or the plates with respect to this surface can be cut to form corresponding steps.

In the case of forms which are strongly contoured in both spatial directions, instead of plates, it is also possible to use columns or webs, which are inserted correspondingly cut to length, so that a three-dimensional contour is approximated. If columns are used, in particular columns, which have a square cross section, a tongue and groove or dovetail connection of these columns offer each other.

In order to form the fine contour, the fine contour or the shaping surface is subsequently printed by means of 3D printing on the substructure thus produced from the plates or columns. The steps formed by the different lengths of the plates or columns are in this case filled on the one hand and on the other hand generates the shaping surface.

The shaping surface or the printed mass are then cured accordingly or interconnected.

If the imprinted mass of metals, optionally metal pigments with a binder, the metal pigments are then preferably fused or sintered together by the action of high heat, for example with a laser.

However, the mass can, in particular for prototypes, also consist of a high-curable synthetic resin, which is optionally filled with minerals or metals in order to achieve high pressure and abrasion resistance.

The invention will be explained with reference to a drawing. It shows:

1 strongly schematized the tool structure according to the invention with interconnected metal plates;

2 : the arrangement after 1 in a plan view;

3 : the arrangement after 1 in a top view, but with square columns.

The tool construction according to the invention 1 or the tool according to the invention 1 has a base plate 3 ,

On the base plate 3 is a plurality of plates or blocks 4 arranged with broad sides next to each other ( 1 . 2 ).

The plates or blocks 4 are made of metal, made of a filled plastic, wood or the like.

The plates or blocks 4 each have one, the base plate 3 diametrically opposite form-sided surface 4a ,

Depending on the contour of a component to be molded 6 own the plates or blocks 4 different heights h, so that through the plates in the x-direction ( 2 ) Following the contour of a height profile is formed.

On this, formed by the different heights h contour is 3D printing a printable mass 2 imprinted, which on its outside the shaping surface 7 forms.

The crowd 2 fills in stages 8th on that between the plates or blocks 4 be formed due to the different height h.

Around the steps 8th To shrink, can be plates or blocks 4 be used with different widths b ( 2 ), whereby in the areas in which the contour changes particularly strongly, the steps are reduced and thereby also the amount of mass is reduced, which must be introduced there. On the one hand, this advantageously accelerates the printing process and, on the other hand, enables a more homogeneous thickness of the composition 2 on the plates or blocks 4 ,

The plates or blocks 4 For example, each have two axial bores (not shown), through which as a fastening device 5 a threaded bolt with appropriate nut 5 is pushed through, so that the plates are held firmly pressed against each other.

In a further advantageous embodiment ( 3 ) are on the base plate 3 instead of plates or blocks 4 columns 9 arranged, with the columns 9 according to the contour of a component to be produced 6 ( 1 ) have different heights h, the width of the columns 9 practicably always the same and the columns 9 for example, have a square cross-section.

Through different heights of the columns 9 It is thus possible to represent a component contour in both the x and y directions.

Around the pillars 9 can hold each other, because through the pillars 9 a grid is specified as a fastening device 5 a tenter can be used, the tenter, for example, consists of corresponding strips that are inserted into each other and so the columns 9 hold each other.

In addition, it is possible to use the columns 9 on adjacent surfaces with grooves and springs (not shown) alone or in addition to a tenter frame.

Around the pillars 9 compact to hold together, the columns can 9 in their abutting surfaces also have dovetail feathers and corresponding dovetail grooves, so that the columns 9 be firmly held together by inserting the dovetail springs in the dovetail grooves.

For arranging the columns 9 at the base plate 3 can the base plate 3 have a corresponding cutout, in which the columns 9 be inserted, the columns 9 can also be screwed through the base plate with this.

Become the pillars 9 or is the tool structure 1 used to create prototype tools, both the plates can 4 as well as the columns 9 Stored in standardized heights and widths and then, without the plates or columns must be cut to size, be put together.

By means of the plates 4 or the columns 9 and the crowd 2 In addition, tools can be created for continuous operation, in addition, the mass 2 and thus also the shaping surface 7 removed from the blocks and placed on another base, if desired.

The on the plates 4 or the columns 9 imprinted mass 2 that is the shaping surface 7 can form metal pigments or metal granules, wherein the metal pigments or the metal granules are fused or sintered in a conventional manner after completion or after the application of certain layer thicknesses by means of high temperature. For example, this is done by the action of laser beams.

In addition, especially for the production of prototypes, plastics and in particular highly hardenable synthetic resins can be printed, which are subjected to a hardening step after completion. A shell made of metal or plastics produced in this way can be left on the blocks or removed therefrom and placed on a possibly over cavities structure, such as a grid structure.

Such a grid structure preferably has corresponding reinforcements in the areas in which particularly high pressure is to be expected.

LIST OF REFERENCE NUMBERS

1

Tool

2

Dimensions

3

baseplate

4

Plate / block

4a

area

5

fastening device

6

Part / workpiece

7

area

8th

step

9

pillar

H

height

b

width

Claims (11)

Tool for forming metal sheets, in particular for deep drawing steel sheet, wherein a rough contour of a workpiece to be formed ( 6 ) with a plurality of plates ( 4 ), Columns ( 9 ) or blocks and on a workpiece ( 6 ) facing surface of the plates ( 4 ), Columns ( 9 ) or blocks, a mass ( 2 ) is printed, which fills the rough contour and the workpiece side forming a surface ( 7 ). Tool according to claim 1, characterized in that the mass ( 2 ) is formed of a high-curable plastic resin or of a printed, and then sintered or molten metal layer. Tool according to claim 1 or 2, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks of metal, plastic, wood or inorganic materials are formed. Tool according to one of the preceding claims, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks on a base plate ( 3 ) are arranged. Tool according to one of the preceding claims, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks with the base plate ( 3 ) are screwed or glued. Tool according to one of the preceding claims, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks screwed together, hidden by grooves and springs or connected to each other via dovetail guides. Tool according to one of the preceding claims, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks corresponding to a rough contour of a workpiece to be formed ( 6 ) have different heights (h). Tool according to one of the preceding claims, characterized in that the plates ( 4 ), Columns ( 9 ) or blocks in the area of strong contour changes have a smaller width (b) than in areas in which the contour changes little or with little slope. Method for producing a tool for forming metal sheets, in particular for deep-drawing steel sheet, characterized in that sheets ( 4 ), Columns ( 9 ) or blocks are arranged together, the plates ( 4 ), Columns ( 9 ) or blocks with a workpiece ( 6 ) facing surface to reproduce a rough contour of the desired workpiece shape, wherein the plates ( 4 ), Columns ( 9 ) or blocks correspondingly have different heights (h) or widths (b), wherein the rough contour of the workpiece ( 6 ) facing surface of the plates ( 4 ), Columns ( 9 ) or blocks a mass ( 2 ) is printed with a 3D printer, with the printing of the steps ( 8th ) between the different height plates ( 4 ), Columns ( 9 ) or blocks, are filled in and a shaping surface ( 7 ) and then the mass ( 2 ) is cured, sintered or melted. A method according to claim 9, characterized in that the rough contour is formed so that it occupies a volume fraction of more than 85% of the tool under a shaping surface. A method according to claim 9 or 10, characterized in that the imprinted mass occupies 5% to 15% by volume of the tool.

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