EP0278046A1 - Device for stamping complex matrix figures out of a metallic strip - Google Patents

Abstract

A progressive tool for punching complex punch patterns from a metal strip in modular design is specified, which allows standardization of different module parts, the overall length of which is kept short and in which strip vibrations are suppressed. For this purpose, a scraper plate is firmly connected to guide columns and springs are used to lift the columns and the scraper plate from a basic position. In addition, spring-loaded tape guide elements for lifting the scraper plate.

Description

The invention relates to a tool for punching complex die-cut images from a metal strip, in which the metal strip is shifted in a clock-wise manner in a slotted band guide elements arranged on both sides of this platen, along a single die plate, and in which the punch above the metal band is stamped by a column guided stamp receiving plate are displaceable in the direction of the surface of the metal strip, are arranged, the stamping stamps passing through a stripping plate above the metal strip and the stripping plate, the stamp receiving plate with the stamps and a pressure plate acting on the stamp receiving plate against the force of spring elements from an upper one Position are movable in the direction of the platen.

Such tools are generally known. They are used to punch die-cut images in contact plates above contact strips. Since the miniaturization of the electrical or electronic components also has to reduce the size of the connection contacts, complicated punching patterns result with very narrow contact paths remaining between the individual punchings. These complex die-cut images cannot be punched out in one punching process, but several punching steps are required.

The so-called follow-up composite tools required for this purpose have a die with recesses corresponding to the individual punching images which the contact strips or contact plates are guided along. The stamps assigned to the individual stamping images are arranged above the contact strips and can be moved in the direction of the contact strip. In order to avoid tilting of the contact strip during cutting and lifting it when pulling the stamp out of the punched-out areas, a stripping plate lies on the upper side of the contact strip during the stamping process, through which the stamps are also guided; she lies on the contact tape just before the stamps touch the tape surface. Only after the stamps have moved out of the punched portions of the contact strip does the stripper plate lift off the contact strip, so that the contact strip can be moved. The scraper plate also serves to guide the sometimes very thin stamps.

The individual punching patterns required for the production of the contact part are carried out in known follow-on composite tools in a single die (cutting plate), which can reach lengths of up to 800 mm and more. With such follow-on composite tools, it is not possible to vary the punch pattern; for minor changes to the die cut, the entire die must be replaced with a correspondingly changed die, even if only a part of the die cut is affected. In order to give the stripping plate, which is moved during the punching process, sufficient stability, this stripper plate must be dimensioned with increasing length in the case of complicated punched parts, whereby the mass to be moved is increased, which ultimately has an effect on a reduced achievable stroke speed. Another problem that arises with such stripper plates is that only one toolmaker can work on this stripper plate during their manufacture.

In the meantime, as has also been seen from the VDI conference report "Stanztechnik-76", published by VDI-Verlag under the heading "Systematic Assurance of Tool Quality", it is possible to divide such subsequent composite tools into modules. Here, the individual workstations, which are necessary to achieve the desired punching pattern, are summarized in function groups and for each group a small, completely independent, ie with its own lower and upper part, worktop and guide columns, follow-up composite tool. Within such a work station, die-cuts are made in module plates.

These so-called inserts are arranged in a base frame next to each other easily and quickly detachably. Since the subdivision of the work stations into functional groups as well as into individual follow-up composite tools requires a larger number of guide columns than a follow-up composite tool, and the connection of adjacent module plates requires additional overall length, the total length of such a tool in modular technology is compared to a follow-up tool. Composite tool with a scraper plate significantly increased. However, this modular design has the advantage that individual module plates can be quickly replaced when the punch pattern is changed, but also in the case of punch patterns prone to failure as part of maintenance work or malfunctions. The individual slots with the individual modules are smaller and lighter at the same time. They can be manufactured, serviced and repaired independently of one another. The individual scraper plates are much smaller and lighter; this has the consequence that the spring assemblies used can be dimensioned weaker. Due to the lower mass of the stripping plates to be moved per work station, an increased punching frequency with up to 2000 strokes per minute is possible.

Based on the prior art described above, the present invention has for its object to provide a follow composite tool in modular design, which allows standardization of different module parts, in which compared to the known module tools, the overall length is reduced and the belt vibrations as a result of that from the upper part , to which the stamps are attached, can be reduced or suppressed with the scraper plate raised. In addition, the dynamic forces that are required for the movement of the wiper plate are to be reduced.

This object is achieved in that the support plate, the scraper plate and the stamp receiving plate are designed as a frame, into which several module plates with the individual punch patterns can be used one behind the other as seen in the tape feed direction, that the scraper plate is firmly connected to at least two columns, that these columns by means of a spring element in each case from a basic position in which the stripper plate is arranged slightly above the support plate, can be moved into a press-on position such that the band guide elements guided at least with one movement component in the direction of displacement of the stripper plate rest under spring pressure with their upper side against the underside of the stripper plates, whereby the sum of the Spring forces of the springs acting on the band guide elements correspond at least to the counterforce caused by the weight of the stripping plate and the spring travel corresponds to the distance between the support plate and stripping plate. With the specified punching tool, higher punching frequencies can be achieved, which is in particular a consequence of the positively guided scraper plate, which is raised by the tape guide elements. The weight of the scraper plate is not increased as before by the drive with which the punch is also moved. Since the scraper plate rests on the top of the tape guide elements, it is only raised so far above the support plate or the top of the tape after the stamps have been pulled out of the punched tape that the contact tape can be fed easily. The only slight gap remaining between the top of the belt and the scraper plate suppresses vibrations at stroke rates greater than 800 per minute. The stroke movement which the stripper plate executes in an upper position in a position in which it rests on a belt should be less than 0.7 mm, preferably less than 0.5 mm. The design of the support plate, the scraper plate and the stamp receiving plate as a frame, in which individual module plates can be used in accordance with the desired punching patterns, allows a simple variation of the tool when the stamping patterns are to be changed. Only the module plates are to be fastened in the frame, while the arrangement of the frames and their connection to the drive remains in the tool, so that an exchange can be carried out quickly. A further advantage results from the fixed connection of the stripping plate to the columns, which together with the stripping plate form a kind of frame which shows increased stability compared to a stripping plate which is displaceably guided on the columns. Each of these columns is acted upon by a spring element which acts in the area of the support plate into which the columns extend, the spring plate holding the stripping plate in a basic position by means of these spring elements, in which the stripping plate is lifted off the belt and thus releases the belt is.

In order to make it easy to replace the stripping plate, the stripping plate is fastened by means of bolts engaging in grooves on the column. To replace the scraper plate, all that is required is to loosen the bolts, which may be conical. The columns in the support plate are preferably displaceably guided in guide bores and the spring elements assigned to the columns in recesses in the guide bores inserted and in such a way that they engage in a groove in the groove on the respective column. In this basic position, the stripping plate should be lifted off the top of the contact strip. In an advantageous embodiment, the groove is a radial annular groove with a wedge-shaped cross section, as seen in the axial direction of the columns, so that the basic position is determined by the spring element engaging in the groove. The angle enclosed by the surfaces of the wedge-shaped groove in cross section should be between 90 ° C and 120 °, so that on the one hand a sufficiently stable position is achieved and on the other hand the columns can still be moved against this spring position against the spring force.

If the recesses in the guide bores are designed in such a way that they completely accommodate the spring elements in the tensioned state, there is the possibility of releasing the columns from the engagement with the spring element.

Spring rings are preferably used as spring elements, which lie in the annular groove, or spiral springs, which are inserted in bores running radially to the column and bear against a ball which engages in the groove of the column.

In order not only to make the tool variable in the area of the frame and module plates, but also with regard to the spring elements that act on the pressure plate, the columns are aligned in at least one row and a continuous bar is placed on the front ends of the columns which act on several spring elements. These springs, which are not assigned to a specific column, can be replaced without special measures, ie in particular regardless of the number of columns. The strips preferably form parts of an upper frame in which they are held in a stop position by the springs. In one design variant, the top frame forms an interchangeable unit with the cross bar and the spring elements. Such a configuration is particularly advantageous in connection with the stripping plate designed according to the invention, since it makes both the lower region and the upper region of the punching tool extremely variable. The specified top frame can, however, also be used in punching tools in which stripper plates and belt guide elements of a different type are used.

• Fig. l einen Querschnitt durch ein Werkzeug im Bereich zweier Säulen,
• Fig. 2 bis Fig. 4 drei verschiedene Stellungen des Werkzeuges nach Fig. l in Querschnittsdarstellungen,
• Fig. 5 einen Schnitt durch ein Oberteil eines erfindungsgemäßen Werkzeuges,
• Fig. 6 und 7 einen Schnitt entlang der Schnittlinie VI-VI in Fig. 5 in zwei verschiedenen Arbeitsstellungen, und
• Fig. 8 eine Draufsicht auf ein Werkzeug ohne Abstreifplatten,

Further details of the invention result from the following description of an embodiment with reference to the drawing. The drawing shows:

• 1 shows a cross section through a tool in the area of two columns,
• 2 to FIG. 4 three different positions of the tool of FIG. 1 in cross-sectional representations,
• 5 shows a section through an upper part of a tool according to the invention,
• 6 and 7 a section along the section line VI-VI in Fig. 5 in two different working positions, and
• 8 is a plan view of a tool without wiper plates,

As can be seen from FIG. 1, the tool has a support plate 1, a scraper plate 2, a stamp receiving plate 3 and a pressure plate 4 one above the other. Support plate 1, stripping plate 2 and stamping plate 3 each have a chamber 5 into which module plates (not shown in more detail) can be inserted. In this case, a module plate with the stamps corresponding to the stamping pattern is screwed into the stamp receiving plate 3, a module plate 5 with guide openings through which the stamping stamps pass and the support plate 1 module plates, which likewise have openings corresponding to the stamping pattern, into the stripping plate 2. The scraper plate 2 is immovably arranged on columns 6 on both sides. In order to be able to release the stripping plate 2, it is fastened to the columns 6 by means of a bolt 7, which engages in a corresponding groove 8 on the columns 6. The column or the corresponding plate is guided displaceably in the support plate 1, the stamp receiving plate 3 and the pressure plate 4.

The mode of operation of the tool shown schematically in FIG. 1 is illustrated with reference to FIGS. 2 to 4. In contrast to FIG. 1, these figures show band guide elements 9 which are inserted into the support plate 1 in blind bores, where they each abut against a spring 10. At its upper end, which projects above the contact surface 11 of the contact plate 1, is parallel to the support surface ll, a slot l2 is present in which the metal strip l3 guided over the support surface ll lies with its edge. In the guide holes l4 of the support plate l, ring grooves l5 are formed, in each of which a spring ring l6 is seated with a round cross section, which in turn engages in a radial groove l7 of the columns 6. This radial groove 17 has a wedge-shaped cross section, the surfaces of the groove preferably enclosing an angle of 110 ° to 120 °.

Figure 2 shows the arrangement in an upper dead center position. In this position, the scraper plate 2 is lifted off the metal strip l3, so that the metal strip l3 can be moved in the slots l2 of the strip guide elements 9 along the contact surface 11 of the contact plate l. In this position, the spring ring l6 lies in the bottom region of the radial groove 17 of the columns 6; the band guide elements 9, which are bolts which are round in cross section, rest with their upper end face on the underside of the stripping plate 2. In the dead center position, the stamp receiving plate 3, against which the pressure plate 4 rests, is moved into an upper end position in which the stamping stamps, not shown, are pulled out of the support plate 1 and the metal strip l3, but guided in the stripping plate 2. In order to initiate a punching process, spring elements 18 arranged in the pressure plate 4, which press against an insert 19, are first moved downwards in the direction of the support plate 1. When the pressure plate 4 is moved downward, the insert l9 comes to rest on the upper side of the column 6 and moves it downward and thus the stripper plate 2 which is firmly arranged thereon and which firmly presses the metal strip l3 against the support plate l. When the pressure plate 4 is moved further, the actual stamping process takes place, in which the stamping stamps attached to the stamp receiving plate 3 penetrate through the metal strip l3. This position is shown in Figure 3; in this position the radial groove l7 of the columns 6 is displaced from the fixed engagement with the spring ring l6 into a lower position in which the spring ring l6 is tensioned. This bottom dead center position is shown in FIG. 4.

Following the bottom dead center position, the direction of movement of the pressure plate 4 is reversed and thus the stamp receiving plate 3 is moved upward with the stamping stamps. The scraper plate 2 initially remains in its pressing position until the punches are completely pulled out of the metal strip l3. When moving the pressure plate 4 upwards The columns 6 are released via the projections 20 on the inserts 19, so that the columns 6 are shifted into the stable position according to FIG. At the same time as the columns 6, the stripping plate 2 is lifted upwards. The tape guide elements 9, against which the springs press l0, support this direction of movement. The slots l2 of the band guide elements 9, which are made wider than the thickness of the metal band guided therein, come with their underside against the underside of the metal band l3 to the system, so that the metal band l3 is lifted off the support plate l and can be moved. This type of belt guide suppresses belt vibrations at high stroke or punch frequencies.

If a replacement of the module plates is required, the columns 6 can be released from engagement with the spring elements l8, for which the ring grooves l5, in which these spring rings l6 are seated, are designed to a depth such that they can completely accommodate the spring rings l6.

Figure 8 shows the structure of the modular tool. It has a lower plate 2l on which individual inserts 22 of standardized length are positioned one behind the other in the central region via guide openings 23. The individual module plates with the respective punching pattern are inserted into the chambers 5 of the individual inserts 22. The inserts 22 are clamped at their lateral edges by fastening elements 24. These fastening elements 24 are spaced apart from one another by means of spacer blocks 25 and engage in undercuts (not shown) in the form of webs and ribs on the lower plate 2l. This type of attachment of the inserts 22 permits a slight variation in the sequence of the inserts, which can be exchanged quickly and easily. At the end of the lower plate 2l, two pillars of the base frame are visible on one long side.

An individual spring element 18, which acts directly on the end of the respective column, is usually assigned to each column 6. However, if the overall length of the tool is increased in such a way that the guiding of the individual plates on two columns 6 (or four columns on both sides of the plates) is not sufficient for an extremely complex stamping pattern, the entire upper part must be used when increasing the number of columns 6 be replaced. In order to avoid this and to make the tool variable with regard to its upper part, an upper part 26 is used, as is shown schematically in FIGS Figures 5 to 7 is shown and that in its function the pressure plate 4 with the spring elements l8 and the inserts l9.

The upper part 26 has a frame 27 with through bores 28 into which individual springs 18 ′, which correspond to the spring elements 18 of the embodiment according to FIGS. 2 to 4, are inserted. The upper part 26 is closed by a cover plate 29 on its upper side. On the underside, a bar 3l is inserted into a longitudinal groove 30, which can move in the region of a guide groove 32, as can be seen from the different positions in FIGS. 6 and 7. To replace the springs l8ʹ after removing the upper part 26 from the punch, the bar 3l is pulled out. In such an upper part 26, the columns 6 are to be exchanged independently of the position of the springs l8ʹ and their spatial arrangement can be changed. When increasing the number of columns, only stronger springs l8ʹ are used in the upper part 26 in a simple manner.

The upper part 26 shown in FIGS. 5 to 7 is not only suitable for a base frame, as can be seen in FIGS. 1 to 4, but it can also be used in tools in which the stripping plate and belt guide elements are guided differently.

Claims (14)

1. Tool for punching complex die-cut images from a metal strip, in which the metal strip is shifted in a clock-wise manner along a single support plate having matrices in both sides of this support plate, with slit-containing tape guide elements, and in the case of the punch above the metal tape, which is provided by a die-holding plate guided on columns are displaceable in the direction of the surface of the metal strip, are arranged, the stamping punches passing through a stripping plate above the metal strip and the stripping plate, the stamp receiving plate with the stamps and a pressure plate acting on the stamp receiving plate against the force of spring elements from an upper position in Are movable in the direction of the support plate, characterized in that the support plate (l), the stripping plate (2) and the stamp receiving plate (3) are designed as a frame, in each of which a plurality of module plates with the individual St seen in the tape feed direction can be used one behind the other that the stripper plate (2) is firmly connected to at least two columns (6), that these columns (6) by means of a spring element each from a basic position in which the stripper plate (2) is slightly above the support plate (l) is arranged, can be moved into a pressing position, that the at least one movement component in the direction of displacement of the stripping plate (2) guides the band guide elements (9) under their spring pressure The upper side bears against the underside of the scraper plate (2), the sum of the spring forces of the springs (l0) acting on the belt guide elements (9) at least the counterforce caused by the weight of the scraper plate (2) and the spring travel the distance between the support (l ) and scraper plate (2). 2. Tool according to claim l, characterized in that the stripping plate (2) on the columns (6) each with a in a groove (8) of the column (6) engaging bolt (7) is attached, 3. Tool according to one of claims l to 2, characterized in that the columns (6) in the support plate (l) in guide holes (l4) are slidably guided and the columns (6) associated spring elements (l6) in recesses of the guide holes (l4), which engage in the basic position in a groove (l7) of the columns (6). 4. Tool according to claim 3, characterized in that the groove is a radial ring groove (l7). 7. Tool according to claim 3 or 4, characterized in that the groove (l7) seen in the axial direction of the columns (6) has a wedge-shaped cross section. 6. Tool according to claim 3, characterized in that the recesses are designed such that they completely accommodate the spring elements (l8) in the tensioned state. 7. Tool according to claim 5, characterized in that the surfaces of the wedge-shaped groove enclose an angle <90 °, in particular <l20 °. 8. Tool according to claim 3 and 4, characterized in that the spring elements are spring washers (L6) which lie in the ring groove (L7). 9. Tool according to claim 3 and 4, characterized in that the spring elements are spiral springs, which are inserted in bores extending radially to the column (6) and bear against a ball which engage in the grooves (l7) of the columns (6) . l0. Tool according to one of claims 1 to 9, characterized in that the stripping plate (2) in the basic position is at a distance <0.5 mm from the surface of the metal strip resting on the support plate (l). 11. Tool according to one of claims l to 9, characterized in that the stripping plate (2) in the basic position has a distance <0.7 mm from the surface of the support plate (l). 12. Tool according to one of claims l to ll, characterized in that the columns (6) are arranged in alignment with one another in at least one row, this row of columns against the force of the spring elements (l8ʹ) acting on the bar (26) act, be postponed. 13. Tool according to claim l2, characterized in that the strips (26) are parts of an upper frame (2l) in which they are held in a stop position by a plurality of springs (l8ʹ). 14. Tool according to claim l3, characterized in that the upper frame (2l) with the bar (26) and the spring elements (l8ʹ) forms an interchangeable unit.

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