EP3606687A1 - Method and device for cutting a workpiece - Google Patents

Abstract

The invention relates inter alia to a method for cutting a workpiece (2), in particular a blank or a component to be cut to size, comprising the steps: inserting the workpiece (2) to be cut into a first cutting device, said cutting device comprising: a first tool half (4) which has at least one first tool holder (8), a least one second tool holder (10) and at least one first cutting means (12); and a second tool half (6) which has at least one first contact surface (14), at least one second contact surface (16), at least one second cutting means (18), at least one third cutting means (20), and a gap (22) between the second (18) and the third cutting means (20); clamping the workpiece (2) by means of the tool holders (6, 8), placing the first cutting means (12) on the workpiece (2), and cutting the workpiece (2) by means of the cutting means (12, 18, 20). The first cutting means (12), the front of which facing the workpiece (2) has two blades, thereby produces a double cut during the cutting process. The invention further relates to a device for cutting a workpiece (2).

Description

 Method and device for cutting a workpiece

The invention relates to a method for cutting a workpiece, in particular a circuit board or a component to be trimmed, comprising the steps of: inserting the workpiece to be cut into a cutting device, the cutting device having a first tool half with at least one first workpiece holder, with at least one second workpiece holder Workpiece holder and having at least a first cutting means and a second mold half having at least a first contact surface, with at least one second contact surface, with at least one second cutting means, with at least one third cutting means and with a gap arranged between the second and the third cutting means, terminals of Workpiece with the workpiece holders, placing the first cutting means on the workpiece, cutting the workpiece by means of the cutting means. The invention further relates to a device for cutting a workpiece, having a first mold half, with a second mold half, wherein the first mold half at least a first workpiece holder, at least one second workpiece holder and at least a first

Cutting means comprises, wherein the second mold half comprises at least a first contact surface, at least one second contact surface, at least one second cutting means, at least a third cutting means and a gap between the second cutting means and the third cutting means.

From the prior art different cutting processes for cutting workpieces are known. Workpieces are usually sheets or (sheet) blanks, which usually undergo a plurality of cutting operations in the context of manufacturing processes. Before the production of a workpiece, it is decided which machine and cutting method are most suitable for these cutting operations. These cutting operations include, for example, shear cutting and laser cutting. The aim of cutting processes is to produce the highest possible cutting edges, which are characterized by a large smooth cut, low or no burr, indentation and breakout, and by a vertical cutting as possible. Depending on the material and tool design, these requirements can be fulfilled more or less well. With shear cutting, soft and tough materials tend to have a high proportion of smooth cut and a low outbreak, with a vertical cutting process. In return, however, higher values for the entry and the ridge must be accepted.

For high-strength and brittle materials, it is the other way round. There are relatively few slippery parts and a high percentage of fracture, which sometimes causes non-vertical cutting surfaces and breakouts. This occurs at most minimal indentation and minimum burr. If the fracture is coarse, this also increases the edge crack sensitivity of a cut edge.

Curing in the edge occurs mainly on soft or tough materials. They are the result of massive displacement changes along and in the depth of the edge.

With regard to the process variables, low cutting gaps and low cutting forces are desired. However, the realization is difficult especially for open cuts, since transverse forces during the cut cause gap widening. Although this leads to lower cutting forces, it ensures larger indentations, burrs and oblique cutting surfaces.

Particularly difficult is the cutting of high-strength and brittle materials. Due to the very high yield strength of the steels, the process forces and thus the load on the cutting tools increase sharply. Particularly stressed are their cutting edges and the adjoining surfaces (front and lateral surfaces). The cutting edges become dull and / or break over time while the Material of the front and lateral surfaces is fatigued by the constant alternating load and is more and more removed in connection with an abrasive cutting material. In order to counteract these effects, numerous investigations and measures for cutting processes with high-strength steels were made. Thus, it would be conceivable to vary the cutting angles of the knives, to modify the geometry of the cutting edges, to cut back pre-cut edges or to use fineblanking. However, low wear with high cut edge quality could not be achieved satisfactorily.

The invention is therefore based on the object of specifying a method and a device for cutting a workpiece, with which in particular the wear of the cutting means is lowered and at the same time an improvement or at least no deterioration of the cut edge quality is achieved.

The above-stated object is achieved according to the invention in that the first cutting means has two cutting edges on its end face facing the workpiece, so that a double cut is produced during the cutting operation by means of the cutting means.

For clamping the workpiece, both sides of the workpiece to be cut are fixed between the workpiece holders and the contact surfaces such that retightening of the workpiece from a region not to be cut during the cutting process is substantially prevented. Preferably, the first cutting means is not yet in contact with the workpiece during the clamping step. It is further preferred that the two workpiece holders move synchronously toward the workpiece and react like a component rigidly connected to one another. The first cutting means is arranged between the two workpiece holders, so that a double cut can be carried out. The clamping force of the workpiece holder is dimensioned such that retightening of the workpiece from an area not to be cut is almost prevented.

In order to produce the double cut, preferably two identical cutting edges are arranged on the front side of the first cutting means facing the workpiece, so that the cut quality is substantially identical in both cuts. In addition, the cutting angle of each cutting edge of the first cutting means is preferably greater than 90 °, optimally the cutting angle is approximately in the range of 98 °. As a double cut is referred to in the invention, a cut, which is composed of two separate cutting lines.

The transverse forces arising during the cutting act against each other in the double cut and thus at least largely cancel each other, so that hardly any transverse forces act on the first cutting means or the cutting edges arranged on the first cutting means. The situation is similar with the second one

Cutting means and third cutting means, so that act on these components substantially little lateral forces.

The second and third cutting means are formed either as a knife or as a knife with adjoining contact surfaces of the second mold half. If the second and third cutting means have adjoining abutment surfaces, then these are aligned substantially horizontally, the adjoining abutment surfaces being aligned with the first and second abutment surfaces in a transition region to the first and second abutment surfaces.

By reducing or eliminating the transverse forces acting on the cutting means, the edge loading of the tools and the adjoining surfaces of the tools (front and lateral surfaces) is considerably reduced, which in turn means a longer tool life and a better cutting quality of the workpiece to be cut. Conditionally. After cutting, the cut strip of the workpiece to be cut, which was located between the two cutting edges of the cutting means during the cutting process, falls into the gap. Since the cutting waste preferably has a narrow width, the loss of material is very low. After the cutting operation is completed, the first tool half is moved away from the workpiece to be cut, so that the two parts of the cut workpiece can be removed.

Preferably, no movement of the second tool half of the cutting device takes place during the process.

The inventive method is particularly suitable for cutting high-strength and brittle materials, but can also be used for cutting soft and tough materials.

For example, the workpiece is made of steel, in particular a high-strength steel. For example, the workpiece is a cold or hot formed steel workpiece. It has been found that in particular workpieces with tensile strengths of up to 1900 MPa and more can be processed by the method according to the invention. In particular, thin sheets having a thickness of 0.1 mm to 5 mm are preferably processed by the method according to the invention.

The first tool half and the first cutting means are preferably an upper tool half and an upper cutting means, respectively. The second tool half, the second cutting means and the third cutting means are preferably a lower mold half, a first lower cutting means and a second lower cutting means, respectively. The first and the second workpiece holder are preferably a first and a second hold-down. The first and the second contact surface of the second tool half are preferably a first and a second bearing surface. If the second or the third cutting means as a knife with adjoining contact surfaces of the second

Mold half, it is possible that the first and / or the second Positioning surface of the second mold half have no contact with a workpiece to be cut, but in particular the contact surfaces of the second and / or the third cutting means. By means of the method according to the invention, it is possible to achieve high smooth-cut portions, a small outbreak without notch effect, a reduced indentation and a very good angularity of the cut surface. The mentioned effects furthermore result in that the operational stability of the cut edges is increased. In addition, the absence of burrs ensures that there is no need for reworking and injuries caused by a burr in the handling of the workpiece can be avoided.

The good or the waste side are defined in normal cutting operations by the cutting line of a workpiece to be cut. Normally, the good side contains the part of the workpiece which is used for further processing, for example in production. In the context of this invention, the parts of the workpiece which are not enclosed by the two cutting lines defined by the cutting edges of the first cutting means and the second and third cutting means can be used for further processing. Accordingly, these areas are referred to in the context of the invention as the first Gutseite and as the second Gutseite. The area between the two cutting lines, in which the part of the workpiece is arranged, which can not be used for further processing and after cutting as a cut strip falls into the gap is referred to in the invention as a waste area. The method can be carried out in particular by a device according to the invention, which will be described in more detail below.

According to a preferred embodiment, an open cut is produced by the cutting process by means of the cutting means. In the case of a closed cut, for example during punching, the opposite sides of the workpiece are necessarily also cut and the cutting system is largely free of lateral forces. this leads to automatically to a low cutting edge load and thus low wear. For the purposes of the invention, open cuts are those cuts which do not have a closed cutting line in the relevant cutting region. A typical cutting process for creating open cuts is clipping. For example, the open cut may have a substantially straight cut line.

In a normal open cut, the cut quality of a waste area is generally worse than the cut quality of a good side, especially since the waste area has no counter-holder down. The good or the waste side is separated by the cutting line of a workpiece to be cut. Normally, on the good side, that part of the workpiece which is used for further processing, for example in production, is why it is not disadvantageous that the cutting quality of the waste side is lower than that of the good side. In the method according to the invention, however, the part of a workpiece enclosed by the cutting lines, that is to say that part of the workpiece which is arranged in the waste area, can not be used for further processing. In the provision of an open double cut, the cut qualities of the two cut areas do not differ from each other, since both good sides are guided and subject to the same cutting conditions. As a result, the waste can be minimized compared to the conventional methods.

The design as a double cut lateral forces can be substantially avoided. In the methods known from the prior art lateral forces can be substantially avoided only in closed sections. In particular, the combination of an open cut and a double cut, however, makes it possible to combine the advantages of closed cuts (for example, avoidance of shear forces) with the advantages of open cuts (eg less exclusion).

Furthermore, it is preferred that the cutting operation is carried out by means of the first cutting means and the second and third cutting means substantially simultaneously. This ensures that the cut quality in both cuts in the is identical. In addition, due to the cuts made at the same time, essentially identical transverse forces are generated which, as a result of their countervailing vectors, thus at least largely cancel each other out, as a result of which the load on the cutting means is reduced.

According to a further preferred embodiment, the first cutting means is guided by the workpiece holders and is connectable to a plunger, wherein the plunger is moved for cutting the workpiece relative to the workpiece holders. In this case, the first cutting means is preferably guided substantially vertically by the two workpiece holders and is detachably arranged on the ram. Such a configuration makes it possible to reliably clamp the two good sides of a workpiece to be cut during the cutting process in such a way that both cuts have a substantially identical cutting quality. By the plunger is movable relative to the workpiece holders, the two good sides of the workpiece to be cut can be fixed during the clamping step without the first cutting means cutting the workpiece. Subsequently, the cutting operation can be performed via a vertical movement of the plunger and an associated vertical movement of the first cutting means. Further, it is preferred that during clamping, a deflection in the region of the workpiece, which is arranged between workpiece holders, is substantially avoided. This is preferably due to a small distance between the two cutting lines to each other or the small width of the waste area. As a result, the part of the workpiece to be cut located in the waste area is clamped between the second cutting means and the third cutting means, whereby bending of the workpiece in the waste area during the clamping step is prevented. This has the effect of providing contrast-cut-like conditions, which results in burr-free cut surfaces, a high level of smooth cut and a very high angularity. According to a further preferred embodiment, the workpiece during the

Cutting process not retracted. This feed-free cutting process can be prevented by a sufficient force application of the workpiece holder or by provided on the workpiece holders teeth. As a result, the quality of the cut edges is further increased and, in particular, the feed is prevented.

Further, it is preferred that a curved cutting profile is generated by the cutting process by means of the cutting means. Preferably, the cutting edges of the first cutting means are preferably designed as hardened and sufficiently thin flat or strip material, which can lead to a simple exchange with a prefabricated, hardened first cutting means. In special cases, this is also conceivable for the second cutting means and / or the third cutting means. By means of such a design of the first cutting means, the field of application of the cutting method can be increased since first cutting edges for curved cuts can also be provided with this method. Due to the configuration of the cutting or cutting means as strip material, the maintenance intervals are reduced and the resulting costs are reduced.

According to a further preferred embodiment, the method is carried out in a cutting tool, in a guillotine cutter or in a lever shears. The method according to the invention is particularly preferably carried out in a guillotine, since in a shearing machine usually both the part of the workpiece which is located on the first good side and the part of the workpiece which is located on the second good side are processed further. Preferably, the method according to the invention can additionally be used both for shearing with a conventional shear angle and for cutting without a shear angle.

The above-mentioned object is also achieved by a device for cutting in that the first cutting means has on its end facing the workpiece two cutting edges defining the face, and in that the first cutting means, the second cutting means and the third cutting means are formed a double Create cut on the workpiece. The resulting advantages and refinements will become apparent from the comments on the aforementioned method according to the invention. The device is in particular configured to carry out the method described above.

According to a preferred embodiment of the device, the first cutting means, the second cutting means and the third cutting means are adapted to produce an open cut on the workpiece. The resulting advantages and embodiments also result from the comments on the above-mentioned inventive method.

Further, it is preferable that the gap or the width of the first cutting means has a width of 1 mm to 20 mm, wherein the gap is dimensioned according to the thickness of the workpiece to be cut and wherein the width of the gap is at most 10 times the thickness of the workpiece, more preferably at most 5 times the thickness of the workpiece is. Preferably, the gap of the device and accordingly also the cutting means are adaptable to the thickness of the workpiece to be cut. For example, a gap width of 1.5 mm with a sheet thickness of 0.5 mm is sufficient, with a 5 mm thick sheet, a gap width in a range of 5 mm to 20 mm is required. By making the gap very narrow, there is substantially no deflection in the waste area of the workpiece during clamping and cutting of the workpiece. As a result, an improved cut edge quality can be provided. Preferably, the gap is made sufficiently deep, so that the cutting waste of a workpiece to be cut can be absorbed and removed. Since the gap is made very narrow, the cutting waste is very low. The resulting blend is comparable to that of a conventional cutting system, which works with trimming to achieve clean cut edges. Preferably, a portioning of the cutting waste can be done by the blades of the first cutting means, the second cutting means and / or the third cutting means a have stepped configuration in the longitudinal direction of the blade or the cutting means. The step height must correspond at least to the thickness of the workpiece to be cut. According to a further preferred embodiment, the first workpiece holder and / or the second workpiece holder has at least one means for fixing the workpiece. The fixing means is designed, for example, as a point or as a point. As a result, the local Nachfließen of material to be cut workpiece is prevented during the cutting process.

Further, it is preferred that a shaft for removing the waste resulting from the cutting operation is arranged under the gap. As a result, the waste produced by the cutting process can be removed. In this case, the shaft is preferably configured in the form of a slide or ramp, so that the resulting waste is automatically removed.

In accordance with a further preferred embodiment, at least one cutting blade of the first cutting means, the second cutting means and / or the third cutting means and in particular the region of the first workpiece holder abutting the workpiece and / or the region of the second workpiece holder abutting the workpiece have a wavy edge. or triangular-shaped design. As a result, occurring cutting impact can be eliminated.

By the preceding and following description of method steps according to the different embodiments of the method, corresponding means for carrying out the method steps by preferred embodiments of the device should also be disclosed. Likewise, by the disclosure of means for carrying out a method step, the corresponding method step should be disclosed. In the following the invention of an embodiment will be explained with reference to the drawing. In the drawing show Fig. 1 is a full section of an embodiment of an inventive

2 shows a full section of the device in a schematic representation during the process step clamping, a full section of the device in a schematic representation during the placement of the first cutting means on a workpiece to be cut,

4 shows a full section of the device in a schematic representation after the process step cutting and FIG. 5 shows a full section of the device in a schematic representation during the removal position.

Fig. 1 shows a full section of an embodiment of a device according to the invention in a schematic representation during the process step insert.

The device has a first upper mold half 4 with a first workpiece holder 8, a second workpiece holder 10 and a first cutting means 12. The first cutting means 12 is guided between the first workpiece holder 8 and the second workpiece holder 10 such that only a substantially vertical movement of the first cutting means 12 is made possible. The first mold half 4 consists of a solid as possible, lowerable composite part.

For movement and control of the first cutting means 24, a plunger 24 is arranged above the first mold half 4, which engages in the guide between the first workpiece holder 8 and the second workpiece holder 10 and relative to the

Workpiece holders 8 and 10 is movable. In this case, the first cutting means 12 via a Push force exerted by the plunger 24 is movable towards a workpiece 2 to be cut. Preferably, the first cutting means 12 is movable downwards against a spring force, so that the first cutting means 12 moves back to its starting position when it is no longer subjected to a compressive force via the plunger 24.

Next, the first mold half 4 preferably not shown guide elements which engage in the second mold half 6 and a very precise relative movement and cutting gap adjustment between the two mold halves 4 and 6 ermögli- chen. Preferably, the first cutting means 12 does not protrude in its initial position relative to the two workpiece holders 8 and 10.

The second tool half 6 is preferably composed of a solid composite part which comprises a first contact surface 14, a second contact surface 16, a second cutting means 18, a third cutting means 20 and a gap 22 arranged between the cutting means 18 and 20. The second contact surface 16 may have a bevel, so that the cut part of the workpiece 2 falls after the cutting operation of the device. The second cutting means 18 and the third cutting means 20 are formed in this embodiment as a knife with adjoining Anla- surfaces. The blades of the second cutting means 18 and the third cutting means 20 limit the gap 22, whereas the contact surfaces of the second cutting means 18 and the third cutting means 20 form a substantially planar transition to the first contact surface 14 and the second contact surface 16. The first mold half 4 and the second mold half 6 can be divided into a first good side 28, a waste area 30 and a second good side 32. The waste area 30 is characterized in that the waste area 30 defines that portion of the cutting process in which the cut-away portion of the workpiece 2 is located. The other two sides of the double cut are defined as good sides 28 and 32. The first cutting means 12 in this case has on its front side two laterally delimiting cutting edges (not shown) which are designed to perform a double and open cut in cooperation with the second cutting means 18 and the third cutting means 20.

2, a full section of the device is shown in a schematic representation during the process step terminals. In this illustration, the upper mold half 4 and thereby also the first workpiece holder 8, the second workpiece holder 10 and the first cutting means 12 is lowered. In this case, the two workpiece holders 8 and 10 preferably move synchronously toward the workpiece 2. The workpiece 2 to be cut is fixed between the workpiece holders 8 and 10 and the abutment surfaces 14 and 16 or the abutment surfaces of the second and third cutting means 18 and 20 such that retightening of the workpiece 2 from an area not to be cut, ie from the one Good sides 28 and 32, during the cutting process is substantially prevented. Further, it can be seen that in the guide between the first workpiece holder 8 and the second workpiece holder 10 has formed a void, since the plunger 24 is not fixedly connected to the first cutting means 12 and is designed to be movable relative to the two workpiece holders 8 and 10.

3 shows a full section of the apparatus in a schematic representation during placement of the first cutting means 12 on a workpiece 2 to be cut. For this purpose, the plunger 24 in the guide formed by the first workpiece holder 8 and the second workpiece holder 10 is vertically in the direction of the first Cutting means 12 moves. As a result, the first cutting means 12 is pressed against a spring holding the cutting means 12 in the original position in the direction of the workpiece 2 until the cutting edges of the first cutting means 12 touch the workpiece 2 to be cut.

In Fig. 4 is a full section of the device is shown in a schematic representation after the process step cutting. In this case, the first cutting means 12 has been pressed by the plunger 24 further in the direction of the workpiece 2, so that the two Cutting the first cutting means 12 and the second cutting means 18 and the third cutting means 20 have made a double cut of the workpiece 2. The process is preferably designed so that the bottom dead center of the process is reached shortly after complete separation. The cut portion of the workpiece 26 is disposed in the gap 22 of the second tool half 6. In this case, the contact force which is exerted on the workpiece via the tool holders 8 and 10 and the contact surfaces 14 and 16 is sufficient to prevent re-flow of the workpiece into the waste area 30. Fig. 5 shows a full section of the device in a schematic representation during the removal position. The two further processed parts of the workpiece 2a and 2b are separated from each other. The arranged on the first Gutseite 28 of the device workpiece 2a is preferably transported over the slope of the contact surface 16 on. In addition, the plunger 24 and the upper mold half 4 are moved away from the cut workpieces 2a and 2b and the first cutting means 12 is moved back to the original position by means of the spring force.

The method was described by means of a punch cut. If, for example, cutting is to be carried out intersecting in a guillotine cutter or in another tool, it is preferred that the cutting means 12, 18 and 20 and the areas of the workpiece holders 8 and 10 bearing against the workpiece are provided with a slight wavy shape or slightly triangular. As a result, any resulting cutting impact can be avoided. The illustrated cutting device can be integrated into the anyway required deep drawing and trimming operations of a press or singular be implemented in a table or lever shears.

Claims

 P a n t a n s p r e c h e

Method for cutting a workpiece, in particular a circuit board or a component to be cut, comprising the steps:

Inserting the workpiece to be cut into a cutting device, the cutting device having a first tool half with at least one first workpiece holder, with at least one second workpiece holder and with at least one first cutting means and a second tool half with at least one first contact surface, with at least one second contact surface, with at least a second cutting means, with at least one third cutting means and with a gap arranged between the second and the third cutting means,

Clamping the workpiece with the workpiece holders,

Cutting the workpiece by means of the cutting means,

characterized,

the first cutting means has two cutting edges on its end face facing the workpiece, so that a double cut is produced during the cutting operation by means of the cutting means.

Method according to claim 1,

characterized,

that an open cut is produced by the cutting operation by means of the cutting means.

Method according to claim 1 or 2,

characterized,

that the cutting operation is carried out by means of the first cutting means and the second and third cutting means substantially simultaneously. Method according to one of claims 1 to 3,

characterized,

in that the first cutting means is guided by the workpiece holders and can be connected to a plunger, wherein the plunger is moved for cutting the workpiece relative to the workpiece holders.

Method according to one of claims 1 to 4,

characterized,

during clamping, a deflection in the area of the workpiece which is arranged between workpiece holders is substantially avoided.

Method according to one of claims 1 to 5,

characterized,

that the workpiece is not retracted during the cutting process.

Method according to one of claims 1 to 6,

characterized,

that a curved cutting profile is produced by the cutting operation by means of the cutting means.

Method according to one of claims 1 to 7,

characterized,

that the method is carried out in a cutting tool, in a guillotine or in a lever scissors.

Device for cutting a workpiece (2),

with a first tool half (4) and

with a second tool half (6), wherein the first mold half (4) comprises at least one first workpiece holder (8), at least one second workpiece holder (10) and at least one first cutting means (12),

 wherein the second tool half (6) has at least one first contact surface (14), at least one second contact surface (16), at least one second cutting means

(18) and at least one third cutting means (20),

 wherein between the second cutting means (18) and the third cutting means

(20) a gap (22) is formed,

 characterized,

 in that the first cutting means (12) has, on its front side facing the workpiece (2), two cutting edges delimiting the end face, and

 in that the first cutting means (12), the second cutting means (18) and the third cutting means (20) are designed to produce a double cut on the workpiece (2).

10. Apparatus according to claim 9,

 characterized,

 in that the first cutting means (12), the second cutting means (18) and the third cutting means (20) are designed to produce an open cut on the workpiece (2).

11. Apparatus according to claim 9 or 10,

 characterized,

 the gap (22) has a width of 1 mm to 20 mm, the gap (22) being dimensioned according to the thickness of the workpiece (2) to be cut and the width of the gap being at most 10 times the thickness of the workpiece ( 2), more preferably at most 5 times the thickness of the workpiece (2).

12. Device according to one of claims 9 to 11,

characterized, in that the first workpiece holder (8) and / or the second workpiece holder (12) have at least one means for fixing the workpiece (2).

Device according to one of claims 9 to 12,

characterized,

in that a shaft for removing the waste produced by the cutting process is arranged under the gap (22).

Device according to one of claims 9 to 13,

characterized,

in that at least one cutting edge of the first cutting means (12), the second cutting means (18) and / or the third cutting means (20) and the regions of the first and / or second workpiece holder (8, 10) abutting the workpiece are a wave or a triangle -shaped design.