EP2036629A1 - Method and device for fine cutting and forming of a workpiece - Google Patents

Abstract

The device has an upper part with a cutting plate (13) formed as a discoidal transfer part with multiple cutting openings (20) fitted to an active element. A machining stage of the upper part is attached to a locking pin (10) and a locking opening (23) in the transfer part for adjusting, fixing and delivering the active element. The locking pin is diametrically opposite at circumference, and is arranged parallel to an axis (A), and fastened in a guide plate (3) of an upper part, where the locking opening is arranged diametrically opposite to the circumference. An independent claim is also included for a method for fine cutting and forming of a workpiece from a band strip.

Description

The invention relates to a device for fine cutting and forming a workpiece from a strip of tape, with several, consisting of active elements such as punch and / or forming element, guide plate for the cutting and / or forming element, arranged on the guide plate ring prongs and pressure plate of an upper part and insert, ejector , Prägeamboss and pressure plate of a base existing processing stages for a machining cycle of cutting, embossing, preforming and / or punching o. The like., The tape strip between closed upper and lower part is clamped and movable in the open position of the upper and lower part in the feed direction.

The invention further relates to a method for fine cutting and forming a workpiece from a Tape strip, in which the tape strip a plurality of, consisting of active elements such as punch, and / or forming element, guide plate, arranged on the guide plate ring teeth and pressure plate of a top and cutting plate, ejector, Prägeamboss and pressure plate of a base machining stages successively a machining cycle of cutting, embossing, preforming and / or perforation o. The like. Be subjected, the tape strip between closed upper and lower part is clamped and processed and moved in the open position of the upper and lower parts in the feed direction cyclically.

State of the art

Fineblanked parts with reshaped functional areas are usually produced in progressive composite fineblanking tools, which comprise several successive stages with follow-on tools. Here, a cut blank is picked up by a cross slide and fed to the next processing stage with the tool open.

From the DE 21 65 224 A1 is a device for successively punching a plurality of mutually identical, for optimum utilization of the material nested parts of a sheet metal strip, or the like. known using a step press, in which a stamping frame is arranged, which serves to receive a cutting punch and a corresponding formed to this die, which are mutually to a Complete cutting or punching tool. The cutting punch and the die are forcibly connected to one another via mechanical links, which after each cut, preferably when the press ram passes through the top dead center position, autonomously effect a synchronous horizontal rotary movement of the punch and die by 180 °. This is done so that the twisting takes place in each case half during the upward and downward stroke of the press ram. The objective of this rotary movement is to achieve a material-saving nesting of the punched blanks.

Furthermore, from the DE 44 09 658 A1 a tool combination for punching machines, in particular for the different processing of window, door profiles o. The like. Known, each tool has a die and a punch driven by the punching machine and the tools for their selective use in relation to the punching machine are positively driven. The dies of the tools are connected to a compact unit and thereby rotatably mounted about an axis which coincides with the direction of movement of the drive of the punching machine. The associated punching members also form a structural unit. Between the units, an effective guide is provided which ensures the same rotational positions and allows an approach and removal of the units.

Despite all these measures of the known state of the art material wasting cuts in the design of the stripe image, especially for smaller parts in the multi-section concept, be provided so that the Forming operations can not affect the punched grid geometry. Ultimately, small parts per stroke generate waste costs that exceed part costs, which means that fine blanking consumes too much material for certain parts.

A further disadvantage is that due to the transport of the cut parts by means of cross slide, the tool must be opened so that the cross slide can transport the cut part in the next processing stage. The specific production times per part increase as a result. In addition, the rams of the presses have to drive largely to their upper and lower dead center, which in turn limits the number of strokes. Often left abandoned or not detected by the cross slide waste slugs in the tool room in addition to disturbances in the manufacturing process and damage to the workpieces.

task

In this prior art, the present invention seeks to provide a method and apparatus for fine cutting small to medium parts, with which it is possible to massively save valuable material, the processing function of the active elements with the transport function of processing level to processing level with simultaneous increase of stroke rate and economic efficiency and to avoid disruptions in the production process by unexposed waste from the tool.

This object is achieved by a device of the type mentioned with the features of claim 1 and by a method having features of claim 12.

Advantageous embodiments of the device and the method are the dependent claims.

The solution according to the invention is characterized in that the cutting plate takes over both the active function, ie active element for the cutting and / or forming process, and the transfer function for transporting the parts from processing stage to processing stage. The cutting plate is therefore designed as a disk-shaped transfer part with a plurality of adapted to the active elements working openings in which the cut piece of work or waste for transport from one processing stage to another is received by clamping, the transfer part about a parallel to the processing direction, located in the center of the transfer part rotatable relative to the active elements of the upper part rotatable perpendicular to this after a stroke on the active elements of the lower part and the work openings are arranged in the transfer section on a common base circle, which corresponds to the distance of the processing stage of the axis, and that the processing elements of the upper part are arranged on the base circle fixedly spaced from each other, wherein the processing stages at least two diametrically opposite to the circumference, fixed in the guide plate of the upper part, arranged perpendicular to the axis locking bolt and a plurality of di Ametral to the circumference arranged latch openings in the transfer section for adjusting, fixing and delivering the active elements are assigned to each other.

The transfer part has to perform the lifting and rotating movement on the one hand held in a mounted on the pressure plate holder guide element for vertical displacement of the transfer member in the direction bolt axis against the guide plate and on the other hand rotatably mounted in the pressure piece pin for rotating the transfer part.

The lifting movement of the transfer part via the pressure piece of the lower part advantageously hydraulically, in which the pressure pin press the guide element in the direction of bolt axis.

The rotational movement of the transfer part then starts when the lifting movement is completed and the active elements of the lower part no longer disturb the rotational movement of the cutting plate.

In order for the latch bolts to slide into the latch openings when the top and bottom are locked, i. Arresting and delivery of the transfer part, can intervene, the axes of locking bolt latch opening lie on a common escape.

The device according to the invention makes it possible, in addition to a single processing cycle, alternatively to carry out the processing stages of a plurality of processing cycles on base circles located concentrically to the virtual axis of rotation of the transfer part. This leads to a significant increase in production quantities.

The feed and discharge direction of the tape strip runs over the virtual axis of rotation of the transfer part, ie beyond the center of the base circle. Each processing cycle is associated with at least one discharge channel, which is arranged depending on the number of processing stages leading to the outside.
The waste slugs are discharged in at least one separate, after running discharge channel. The removal is preferably carried out by an outward blowing or tape transport.
The separate discharge of waste slugs has the advantage that the discharge of the finished workpieces is completely separated from the waste discharge. The risk that a disturbance in the production process will occur due to unexploded waste is thus largely ruled out.

The method according to the invention makes it possible to clamp the work piece cut out of the tape strip and / or the blank in a clamping manner in a work opening located on a circular path and to store it in the work opening. By a lifting movement with subsequent rotation about a, the distance of the active elements from each other corresponding amount stored in the respective work piece workpiece progressively reaches the next processing stage, wherein at each rotation step, the active elements of the upper part and the active elements of the lower part brought to coincide and after adjusting and Close to complement a pair of the respective processing level.

The method according to the invention has the great advantage that several processing cycles can be carried out simultaneously, wherein a first processing cycle is carried out on a first base circle and a further processing cycle on a base circle which differs from the first base circle.

Of particular advantage is further that a separate transport of the finely cut and formed workpieces within the workpiece by means of cross slide is no longer necessary. In addition to its active function, the insert also handles the transport function. The workpieces are completely cut out and separated from the stamped grid, so that material-wasting cuts, especially in small parts no longer have to be accepted. This leads to considerable material savings in small and medium-sized fineblanked parts, which means that fineblanking remains lucrative despite significant increases in steel prices.

The fact that the finely cut and formed workpieces clamped recorded after the cutting or forming operation in the work openings and transported to the next processing stage, there is the advantage that the workpieces can not be damaged by any remaining waste in the tool room during fineblanking or forming process.

As a result of the transfer of the workpieces by means of the cutting plate and the omission of a separate slider for transporting the parts of the plunger stroke of the press in total be significantly reduced, making it possible to increase the stroke rate, ie the number of cycles considerably.

Further advantages, features and details of the invention will become apparent from the following description with reference to the accompanying drawings.

embodiment

The invention will be explained in more detail below to an embodiment.
It shows

Fig. 1 a section through the device according to the invention in the open position of the upper and lower part along the line AA Fig. 2 .

Fig. 2 a plan view of the inventive device according to Fig. 1 .

Fig. 3 a section through the device according to the invention in the processing stage "cutting" at top dead center according to the inventive method,

Fig. 4 a section through the device according to the invention in the processing stage "embossing" at top dead center according to the inventive method and

Fig. 5 a section through the device according to the invention in the processing stage "ejection" at top dead center according to the inventive method.

The Fig. 1 shows the basic structure of the inventive device for producing a finely cut and formed workpiece W. The device according to the invention has an upper part 1 and lower part 2. The upper part 1 of the device according to the invention includes a guiding plate 3 having a ring point 4, a punch 5 for punching a tape strip 6 , a cutting punch 7 for cutting a perforated blank 8 from the tape strip 6, an embossing punch 9 (see Figure 4 ) for performing a stamping operation on the cut blank 8 and at least two locking bolts 10. The active elements punch 5, cutting punch 7 and stamp 9 are guided in the guide plate 3. Their respective working direction is perpendicular to the tape strip 6. The two locking bolts 10 are disposed near the outer edge of the guide plate 3 and are diametrically opposite.
On the guide plate 2 presses the hydraulic pressure upper pressure pin 11th

The lower part 3 is formed from a socket 12, a disc-shaped cutting plate 13 with guide element 14, a waste channel 15, an ejector 16, an embossing boss 17 and a central bearing pin 18 which is fixed on the lower pressure plate 19. Cutting plate 13 and guide member 14 form a common component which is rotatable. In the cutting plate 13 corresponding cutting openings 20 are provided, which are associated with the active elements 5, 7 and 8 respectively. On the bearing pin 18, the cutting plate 13 supports centrally with its guide element 14.
The guide member 14 is supported on its outer periphery on the socket 12, in the plane E between the guide surfaces of the socket 12 and guide member 14 an unillustrated drive element acts, such as a stepper motor for generating the required drive torque for rotating the cutting plate 13 to their on the axis of the journal 18 located virtual axis A.

On the guide member 14, a lower under hydraulic pressure pressure pin 21 acts, with the aid of the cutting plate 13 together with its guide member 14 can perform a defined lifting movement in the direction perpendicular to the tape strip 6. The ejector 16 as a counter-holder for the cutting punch 7 is supported by a further under pressure hydraulic pressure pin 22.

In the disc-shaped cutting plate 13 are near its outer periphery a plurality of bolt openings 23 which are diametrically opposed. In closed delivery of upper and lower part 1 and 2, the two diametrically opposed locking bolts 10 each engage in two latch openings 23. The bolt axis openings 23 are distributed along the circumference of the cutting plate 13 so that upon engagement of the locking bolt 10, the corresponding active elements of the upper and lower part 1 and 2 together an active pair , ie each can form a processing stage. The tape strip 6 is in the closed position of Clamped upper and lower part between the guide plate 2 and cutting plate 13 and the ring prong 4 already penetrated into the tape strip 6.

The punch 5 and the corresponding cutting opening 20 of the cutting plate 13, cutting punch 7 in the upper part 1 and ejector 16 in the lower part 2 and die 9 in the upper part 1 and Prägeamboss 18 in the lower part 2 form corresponding pairs of action, as in below Fig. 2 is described in more detail, lie on a common base circle GK, which has the virtual axis A to the center.

The Fig. 2 shows the device according to the invention in plan view, which illustrates the sequence of the method according to the invention.
In the first step I, the blank 8, possibly also an inner mold is cut into the working opening 20 of the cutting plate 20 from the Teilereihe T1 of the tape strip 6 and not ejected. The blank 8 remains in the working opening 20. When opening the upper part 1 and lower part 2 of the device according to the invention, the cutting plate 13 including guide member 14 is lifted by the hydraulically actuated pressure pin 21 and rotated with the present in the cutting opening 20 blank 8 in the next following working position. In the example shown here, the rotation is in the clockwise direction to the rear of the device. Of course, it also belongs to the invention when the direction of rotation is counterclockwise. In the second step II, the upper and lower parts 1 and 2 are closed, in which the locking bolts 10 engage in the corresponding locking holes 23 of the cutting plate 13. The cutting plate 13 is now through the Locking bolt 10 is locked and it can on the blank 8, the next operation, for example, embossing or ejecting the slugs 26 in a channel 15 (see also Fig. 1 ). In the third step III, the cutting plate 13 is in turn raised with the remaining in the working opening 20 blank 8 when opening the upper and lower part and rotated until the next following working position (processing stage) is reached. The cutting plate 13 is locked as described in the second step and closed upper and lower parts. The corresponding work operation is carried out, whereby the work steps repeat until the machining of the part is completed.
In the fourth step IV, the finished workpiece is ejected from the cutting opening 20 of the cutting plate 13 in a channel 25 and removed for example by blowing out of the interior of the upper and lower part. After opening the upper and lower part 1 and 2, raising and turning the cutting plate 13, the released cutting opening 20 in the cutting plate 13 reaches the working position in the part T2 row of the tape strip 6, so that a reworking cycle in the clockwise direction on the front of the device can be carried out.

The feed direction Z of the tape strip 6 in the device according to the invention via the center, ie the virtual axis A, so that it is readily possible to use different width tape strips 6, when the base circle GK is adjusted accordingly for the arrangement of the individual processing stages.

Depending on the number of necessary processing cycles, the individual pairs of action can be on concentrically arranged base circles GK, each having from the virtual axis of rotation A of the cutting plate 13 different radii R, so that several processing operations can be performed simultaneously.

Each processing cycle is a channel 25 for the removal of the finished workpieces to the outside. The discharge direction AR of the finished parts can vary according to the number of active pairs (processing stages). The angles α can therefore vary with respect to the feeding direction of the tape strip 6.
The channel 24 for the removal of the Abfallbutzen runs perpendicular to the feed direction of the tape strip 6 and is thus completely separated from the removal of the finished parts, so that corresponding disturbances are excluded by remaining remaining in the tool room slug remnants.

The Fig. 3 to 5 illustrate the steps cutting, embossing and ejection. In Fig. 3 Upper and lower part 1 and 2 is closed and the tape strip 6 clamped between the guide plate 3 and socket 13. The locking bolt 10 engages in the latch opening 23. The cutting plate 13 is locked. The punch 5 and the punch 7 have cut corresponding parts in the working opening 20 of the cutting plate 13. The Fig. 4 shows the work embossing. Upper part 1 and lower part 2 of the device according to the invention is closed and the cutting plate 13 is locked by the locking bolt 10. The embossing stamp 9 and embossing boss 17 are in working position.
In Fig. 5 the part output of finished fine cut and formed workpieces is shown. In the channel 25 a finished part is ejected and can be discharged, for example by blowing.

Oberteil

1

Unterteil

2

Führungsplatte

3

Ringzacke

4

Lochstempel

5

Bandstreifen

6

Schneidstempel

7

Rohling

8

Prägestempel

9

Riegelbolzen

10

Oberer Druckbolzen

11

Fassung

12

Schneidplatte (Matrize)

13

Führungselement

14

Abfallkanal

15

Auswerfer

16

Prägeamboss

17

Lagerzapfen

18

Untere Druckplatte

19

Schneidöffnungen in 13

20

Unterer Druckbolzen

21

Unterer Druckbolzen für 16

22

Riegelöffnungen

23

Abführkanal für Fertigteile

24, 25

Abfallbutzen

26

Virtuelle Drehachse

A

Abführrichtung für fertige Teile

AR

Achsflucht von 10

B

Grundkreis

GK

Radius von GK

R

Erste Teilereihe auf 6

T1

Zweite Teilereihe auf 6

T2

Werkstück

W

Zuführrichtung, Vorschubrichtung von 6

Z

Winkel Abführrichtung der Fertigteile

α

Arbeitsschritte/Bearbeitungsstufen

I,XI,III,IV

LIST OF REFERENCE NUMBERS

top

1

lower part

2

guide plate

3

V-shaped projection

4

punch

5

tape strips

6

cutting punch

7

blank

8th

dies

9

locking bolt

10

Upper pressure pin

11

version

12

Cutting plate (matrix)

13

guide element

14

waste channel

15

ejector

16

coining anvil

17

pivot

18

Lower pressure plate

19

Cutting openings in 13

20

Lower pressure pin

21

Lower pushpin for 16

22

latch openings

23

Discharge channel for finished parts

24, 25

moil

26

Virtual rotation axis

A

Discharge direction for finished parts

AR

Axis flight of 10

B

base circle

GK

Radius of GK

R

First part series on 6

T1

Second part series on 6

T2

workpiece

W

Feed direction, feed direction of 6

Z

Angle discharge direction of the finished parts

α

Operations / processing stages

I, XI, III, IV

Claims (18)

Device for fine blanking and forming a workpiece from a strip of tape, with a plurality of annular serrations (10) and / or forming element (9), guide plate (3) for the cutting and / or forming element, arranged on the guide plate 4) and pressure plate of an upper part (1) and cutting plate (13), ejector (16), Prägeamboss (17) and pressure plate of a lower part (2) existing processing stages for a processing cycle of cutting, embossing, preforming and / or punching o. The like. , wherein the tape strip (6) clamped between the closed upper and lower part and in the open position of the upper and lower part in the feed direction (Z) is movable, characterized in that the cutting plate (13) as a disc-shaped transfer member with a plurality of adapted to the active elements Cutting openings (20) is formed, in which a cut blank (8) is received for transporting from one processing stage to the other by clamping, wherein the Transfer part about a parallel to the processing direction, located in the center of the transfer part virtual axis (A) against the active elements of the upper part (1) rotatable, perpendicular to this after a stroke on the active elements (5,17) of the lower part rotatable and the cutting openings (20 ) are arranged in the transfer section on a common base circle (GK) whose radius (R) corresponds to the distance of the processing stage from the axis (A), and that the processing stages of the upper part on the base circle (GK) are arranged fixedly spaced from each other, wherein the Processing stages at least two diametrically opposite to the circumference, in the guide plate (3) of the upper part attached, arranged parallel to the axis (A) Lock bolt (10) and a plurality of diametrically opposite to the circumference arranged latch openings (23) in the transfer part for adjusting, fixing and delivering the active elements are assigned to each other. Device according to claim 1, characterized in that the transfer part comprises a guide element (14) held by a holder (14) arranged on the pressure plate (19) for vertically displacing the transfer part in the direction of the locking bolt axis (B) against the guide plate (3) and one on the pressure piece () fixed pin (18), wherein the transfer part is rotatable about the pin (18). Apparatus according to claim 1 and 2, characterized in that the cutting plate (13) and guide element (14) form a common component. Apparatus according to claim 1 and 2, characterized in that the guide element (14) in the plane

between step (12) and guide element (14) on the outer circumference of the guide element (14) engaging stepping motor is assigned to rotate the transfer part of processing stage to processing stage. Apparatus according to claim 1, characterized in that the axes of locking bolt (10) and bolt opening (23) in the closed position of the upper and lower part (1,2) are arranged on a common alignment (B). Apparatus according to claim 1, characterized in that all processing stages of a processing cycle on the base circle (GK) are arranged. Apparatus according to claim 1, characterized in that the processing stages of a plurality of processing cycles are arranged on concentric to each other base circles (GK), which have correspondingly different distances from the axis (A) of the transfer part. Apparatus according to claim 1, characterized in that the supply and discharge direction (Z, AR) of the tape strip (6) over the center of the base circle (GK) is located. Apparatus according to claim 1, characterized in that at least one discharge channel (24) is provided for finished workpieces whose direction is arranged variable with respect to the discharge direction (AR) of the tape strip (6). Apparatus according to claim 1, characterized in that at least one discharge channel (25) is provided for finished workpieces whose direction is arranged variably with respect to the feed direction (ZR) of the tape strip (6). Apparatus according to claim 1, characterized in that at least one discharge channel (15) is provided for waste slugs. A method for fine blanking and forming a workpiece from a tape strip, wherein the tape strip a plurality of processing elements consisting of knitting elements such as punch, and / or forming element, guide plate on the guide plate ring teeth and pressure plate of a top and cutting plate, ejector, Prägeamboss and pressure plate of a base existing processing stages successively a machining cycle of cutting, embossing, preforming and / or punching o. The like. Subjected, the tape strip between closed upper and lower part is clamped and processed and moved in the open position of the upper and lower part in the feed direction cyclically, characterized in that the cut-out workpiece and / or the blank received or stored by lying on a circular path cutting opening of the cutting and by a stroke with subsequent rotation of the cutting plate to a, the distance of the active elements from each other corresponding Betr ag, the active elements of the upper part located on a circular path are successively supplied step by step, wherein brought in each rotation step, the active elements of the upper part and the active elements of the lower part to cover and complement after adjusting and closing to a pair of the respective processing stage. A method according to claim 11, characterized in that the movement along the circular path of the working openings in the cutting plate and the movement along the circular path of the active elements of the upper part take place on a common base circle. Method according to Claims 12 and 13, characterized by the following successive operating steps: I) Cutting the blank in the working opening of the cutting plate and its whereabouts in the working opening with closed upper and lower part with subsequent lifting of the cutting plate on the active elements of the lower part and gradual rotation of the respective working opening of the cutting plate with the upper and lower part open until the next processing stage, II) aligning and locking the active elements with the closing of the lower and lower part and performing another forming operation, III) re-executing the process according to steps b and c, repeating this until the processing of the part is completed, IV) ejection and blowing out of the finished part with the upper and lower parts open, with the cutting plate being rotated after lifting until the free machining stage work opening is reached to perform a reworking cycle. A method according to claim 12, characterized in that a plurality of processing cycles are performed simultaneously, wherein a first processing cycle on a first base circle and a another machining cycle is performed on a further base circle whose radius is different from that of the first base circle. Method according to 12 to 15, characterized in that the tape strip is guided over the center of the base circle. The method of claim 12 to 15, characterized gekezeichnet that the finished workpieces are removed by blowing or tape transport from the open upper and lower part. The method of claim 11 to 14, characterized thereby, that the waste slugs are removed by blowing or belt transport from the closed upper and lower part.

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