WO2013098154A1 - Tool die for a tool unit - Google Patents

Abstract

The invention relates to a tool die (12) for a tool unit for punching and/or shearing work pieces (17), particularly metal sheets, comprising a tool body (26) that has a tool opening (24), running across said tool body (26), for engagement with a punch (15) of a punching tool (14); comprising an end-face (21) that is provided on said tool body (26) in order to support a work piece (17); and comprising a cutting edge (33) which surrounds the tool opening (24) and is surrounded by a peripheral depression (32) that passes into said end-face (21), this cutting edge (33) being formed by a rake face (34) which is inclined at a rake angle (35) relative to said end-face (21). The rake face (34) passes seamlessly into a base surface (37) or a lowest point of the depression (32), and said depression (32) extends, with a curved surface (40), from there to the end-face.

Description

Tool die for a tool unit

The invention relates to a tool die for a tool unit for shearing and / or punching workpieces, in particular sheets.

Conventional tool units for shearing and / or punching workpieces, in particular sheets, comprise a tool die with a tool opening and a punch with a punch. During the punching operation of a workpiece with a tool unit, the punching tool is moved toward the tool die, so that the punching punch engages with the tool opening in order to punch out a waste part or a good part from the workpiece carrier lying therebetween. This waste part or good part falls through the tool die down through the tool opening. In such conventional tool dies, one end face of the tool die abuts at a right angle to the tool opening to form a circumferential cutting edge. With such tool units, burr formation occurs during the punching of workpieces at the cutting edge, with the burr projecting downwardly from an underside of the workpiece. Such a projecting burr leads to damage during further processing. Therefore, post-processing to remove the burr is required.

In order to avoid this burr formation, EP 0 734 799 B1 proposes a tool die which adjoins the tool opening and, with respect to the end face of the tool body, proposes an increase which is increased in the direction of the punching tool relative to the end face. As a result, during the punching process, the forming cutting burr is moved into an opening of the workpiece, in that a groove formed opposite the underside of the workpiece toward the workpiece center is formed, from which the cutting burr in turn extends to the underside of the workpiece. Such a configuration of the workpiece die is also known from JP 63101029 A, JP 08-332529 A and JP 03-275224 A.

Although such an embodiment makes it possible that burr formation does not present an obstacle to subsequent processing and is not removed, this tool die has the disadvantage of providing an increase relative to the face of the die which is detrimental to moving the workpiece and that burr formation still remains, even if it does not protrude from the bottom of the workpiece.

Furthermore, EP 2 153 915 A1 discloses a tool die for a tool unit, in which a cutting edge of the tool die is surrounded by a circumferential recess, which is formed by a rake face which is inclined relative to an end face on which the tool body rests and drops constantly. At the end of the rake face a connecting line is provided, which leads directly to the front side, whereby a step-shaped return from the edge of the cutting edge opposite the cutting edge is given to the end face. An analogous arrangement is disclosed in JP 09-47828 A. Although these two arrangements allow an improvement over the above-described matrices with respect to the burr formation, a sufficiently large and annoying burr formation still remains.

The invention has for its object to provide a tool die for a tool unit, by which a further reduction of the burr formation while maintaining a shift of the burr formation in the workpiece opening is made possible to the burr freedom of a cutting edge.

This object is achieved by the features of claim 1. Further advantageous embodiments and further developments are specified in the further claims.

By the design of a cutting edge on the tool die with an adjacent circumferential recess, wherein the cutting edge is formed by a rake face which is inclined relative to the end face of the tool body and merges smoothly into a base or a deepest point of the recess, from there If a curved surface extends to the front side of the tool body, the burr formation is reduced or even avoided. Moreover, in the case of reduced burr formation, it may be achieved that the burr does not protrude downwardly from a bottom surface of the workpiece but is displaced inwardly into the blanking opening in the workpiece. Furthermore, the integration of the rake face in the recess has the advantage that a force profile can be determined by the cutting surface with a rake face at a predetermined angle, which changes when cutting by overbending. As a result, an improved design of the cutting edge on the workpiece can be achieved.

According to a first preferred embodiment of the invention, the depression is semicircular or elliptical. Depending on the parameters to be optimized for the punching process, the recesses can be selected accordingly, wherein the geometry of the recess is significantly adapted to the rake face to form a predetermined rake angle of the cutting edge.

An alternative embodiment of the invention has an egg-shaped or teardrop-shaped depression, in which preferably the greatest depth is provided away from the cutting edge. The alternative embodiments also allow for reduced burr formation.

Preferably, a plateau level is provided between the cutting edge and the rake face which merges into the recess. As a result, a defined displacement of the cutting degree counter to the cutting direction into the workpiece opening can be achieved.

Furthermore, the plateau level preferably lies in the plane of the end face of the workpiece body. As a result, elevations with respect to the end face of the tool body of the tool die can be avoided, and a disturbing edge impeding the workpiece transport can be dispensed with.

According to a further preferred embodiment of the invention, the cutting edge lies in the plane of the end face of the tool body. By this arrangement, elevations are avoided with respect to the end face of the tool body of the tool die. This eliminates a workpiece transport obstructing Störkante.

A further preferred embodiment of the invention provides that the cutting edge is formed recessed towards the end face of the tool body to the center of the tool body, whereby also a simplified production and a disability-free workpiece movement are possible.

The tool opening preferably has a conical surface section adjoining the cutting edge, forming a clearance angle of the cutting edge. As a result, the punching or shearing work can be further refined to reduce or prevent the formation of burrs. Preferably, an adaptation of the rake angle and the clearance angle to the material thickness and / or the material of the material to be machined of the workpiece, in order to achieve an optimization up to the burr freedom.

The invention and further advantageous embodiments and developments thereof are described in more detail below with reference to the examples shown in the drawings and explained. The features to be taken from the description and the drawings can be applied individually according to the invention individually or in combination in any combination. Show it:

FIG. 1 shows a perspective view of a tool die according to the invention for a tool unit,

FIG. 2 shows a schematic view of a punching process with the tool die according to the invention according to FIG. 1,

FIG. 3 shows a schematic sectional illustration of the tool die along the line A-A in FIG. 1,

FIG. 4 a shows a schematically enlarged detailed view D according to FIG. 3,

FIG. 4b shows a schematically enlarged detailed view D of an alternative embodiment according to FIG. 3,

FIG. 5 shows a schematically enlarged view of a cutting region of a workpiece produced with the tool die according to FIG

FIG. 6 is a schematic sectional view of an alternative embodiment of the workpiece die according to FIGS. 1 to 4.

FIG. 1 shows a perspective view of a tool die 11 according to the invention. This tool die 11 is part of a tool unit 12 shown schematically in FIG. 2, which comprises a punching tool 14 with a punch 15 and the tool die 11. The punching tool 14 may include a punch guide 16 for guiding the punch 15.

The tool die 11 comprises an end face 21 on which an underside 22 of the workpiece 17 rests during machining. In this end face 21 of the tool die 11, a tool opening 24 is provided, which is surrounded by a cutting edge 33. Between the tool die 11 and the punching tool 14, the workpiece 17 is positioned for machining. To produce a workpiece opening 43 in the workpiece 17, the punch 18 engages in the tool opening 24. As a result, a waste part 30 or a good part is formed, which is brought out via a lower side on the tool die 11. In order to facilitate a transport of the waste part 30 or good part, an enlarged recess 28 may be provided on the underside of the tool die 11, which adjoins the tool opening 24.

To further discuss the inventive design of a cutting edge 33, which is adjacent to a recess 32 which surrounds the tool opening 24, reference is made to the following figures 3 and 4 closer.

4a shows an enlarged detail D according to FIG. 3. According to this embodiment, the cutting edge 33 preferably lies in the plane of the end face 21 of the tool die 11 and delimits the tool opening 24. The recess 32 is formed between the cutting edge 33 and the end face 21 of the tool die 11 , which goes away from the tool opening 24 again in the end face 21. Immediately adjacent to the cutting edge 33 and extending into the recess 32, a rake surface 34 is formed, which comprises, for example, a width of the surface according to the illustrated double-headed arrow. This rake surface 34 is disposed at a predetermined rake angle 35 to form and determine a cutting geometry of the cutting edge 33. Adjacent to the clamping surface 34, a base surface 37 of the recess 32 is provided which, for example, comprises a planar surface section 39 and subsequently opens into the front side 21 by means of a curvature or a curved surface 40. The depression 32 shown in FIG. 4a is designed in the form of a drop, with the tip region of the drop being aligned with the cutting edge 33. Alternatively, the recess 32 may also be formed egg-shaped. The base 37 may also be reduced so that only a lowest point is formed.

In addition to the rake surface 34, which is determined by the rake angle 35, the cutting edge geometry can be determined by a clearance angle 41. In the embodiment of Figure 4a, the clearance angle is equal to 0 °. This can also include several degrees. In order to optimize the cutting edge 33 up to the burr freedom, a determination of the rake angle 35 and the clearance angle 41 can take place as a function of the material to be processed, thereby defining the wedge angle of the cutting edge 33.

FIG. 4b shows an alternative embodiment to FIG. 4a of an enlarged detail D according to FIG. This embodiment deviates from the embodiment shown in FIG. 4 a in that a plateau level 36 is provided between the cutting edge 33 and the rake surface 34. This plateau level 36 is preferably located in the plane of the end face 21 of the tool body 26 and may also be arranged offset in relation to the end face 21 of the tool body 26 in the tool opening 24. The recess 32 shown in Figure 4b is, for example, teardrop-shaped or egg-shaped or elliptical. In this case, in the depression 32, in turn, a base 37 may be provided in the deepest region, which comprises a flat surface section or the surface section may also be reduced to a lowest point. The depressions 32 according to FIGS. 4a and 4b can have a continuously curved surface, so that, starting from the rake surface 34, a step-free depression 32 is formed over a lowest point in the depression up to the extension into the end face 41. This embodiment of the recess 32, which is free of edges, steps or sudden transitions, allows a special reduction in burr formation and can lead to burr freedom.

This embodiment according to the invention of the cutting edge 33 with a recess 32 immediately adjacent thereto with respect to the end face 21 makes it possible for a force profile to be changed during the cutting by an overbending of the cutting edge 33. In particular, by the embodiment of Figure 4b by a cutting edge 42 can be achieved in a workpiece opening 43 of FIG 5. This cutting edge 42 of the workpiece opening 43 of the workpiece 17 comprises a considerably reduced burr formation, in which a burr 44 is displaced towards a bottom side 45 of the workpiece 17 in the direction of the workpiece center or comprises a ridge reduction 45. Thus, the ridge 44 does not protrude from the underside 55 of the workpiece 17. In addition, the ridge 44 includes only a minimum ridge width 46 bounded by a plateau portion 47 defined by a trough entrance angle 48. This sectional view according to FIG. 5 furthermore shows that a smooth-cut height 50 adjoins an edge retraction width 49 and, in turn, has a fracture surface height 52 which is offset by the formation of the burr 44. Thus, the ridge tip relative to the bottom 55 as well as against the blade cutting height 50 is displaced in each case inward, so that there is no impairment in the further processing at a minimally remaining ridge 44 is given.

When looking through the cutting edge 33 of the tool die 11 according to FIG. 4 b and the cutting edge 42 of the workpiece 17, it can be seen that the plateau plane 36 of the tool die 11 defines a plateau section 47 of the workpiece 17. The rake angle 35 of the rake surface 34 of the tool die 11 determines the trough entrance angle 48 of the ridge 44 with respect to a portion between the bottom 55 and the plateau portion 47 of the workpiece 17. Preferably, the plateau level 36 on the tool body 26 is smaller than the rake face 34 adjacent thereto.

FIG. 6 shows an alternative embodiment of the recess 32 for the exemplary embodiment according to FIGS. 1 to 4. In this embodiment, the recess 32 has a semicircular cross-section.

In this alternative embodiment as well, a plateau level 36 may be provided between the cutting edge 33 of the rake face 34.

The geometry of the recess 32 is determined in a region adjacent to the cutting edge 33 by the width and the angular arrangement of the rake face 34. Subsequent thereto, that is to say in the further course with respect to the base surface 37, the recess 32 can comprise different contours.

Claims (8)

1. Tool die for a tool unit (12) for punching and / or shearing workpieces (17), in particular sheets, with a tool body (26) comprising a tool opening (24) for engagement of a punch (15) of a punching tool (14) passing through the tool body (26) and having an end face (21) provided on the tool body (26) for supporting a workpiece (17) and a cutting edge (33) surrounding the tool opening (24), the cutting edge (33 ) is surrounded by a circumferential recess (32), which merges into the end face (21), characterized in that the cutting edge (33) is formed by a rake face (34) which lies in a rake angle (35) with respect to the end face (21 ), and the rake surface (34) merges smoothly into a base surface (37) or a lowest point of the depression (32), and the depression (32) extends therefrom with a curved surface (40) to the end face.
2. Tool die according to claim 1, characterized in that the recess (32) has a semicircular or elliptical cross-section.
3. Tool die according to claim 1, characterized in that the recess (32) comprises a pear-shaped or tear-shaped depression, in which preferably the greatest depth is provided away from the cutting edge (33).
4. Tool die according to claim 1, characterized in that a plateau level (36) is provided between the cutting edge (33) and the rake surface (34).
5. Tool die according to claim 4, characterized in that the plateau level (36) in the plane of the end face (21) of the tool body (26) or against the end face (21) of the tool body (26) is set back in the direction of the center of the tool body (26).
6. Tool die according to claim 1, characterized in that the cutting edge (33) in the plane of the end face (21) of the tool body (26).
7. Tool die according to claim 1 to 5, characterized in that the cutting edge (33) relative to the end face (21) of the tool body (26) is recessed towards the center of the tool body (26) out.
8. Tool die according to one of the preceding claims, characterized in that the tool opening (24) has a conical surface section adjoining the cutting edge (33), forming a clearance angle (41).

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