EP0891235A1 - Precision blanking press with knife-edged ring and counter cylinder - Google Patents

Abstract

The press slide of a hydraulically or mechanically driven precision blanking press is non-positively connected with a crosshead by means of columns. The knife-edged ring cylinder is integrated in the crosshead and the supporting force of the knife-edged ring cylinder is taken up by the slide. During a cutting stroke, there is no relative movement between the knife-edged ring cylinder with piston and the slide. The counter cylinder is located in the lower crosshead of the stand. During a cutting stroke, there is no relative movement between the counter cylinder and the workpiece in the tool. The working force of the main drive is not reduced by the pressing force of the knife-edged ring and counter cylinder.

Description

 Fineblanking press with ring-serrated and counter cylinder

FIELD OF APPLICATION OF THE INVENTION The invention relates to a hydraulically or mechanically driven fineblanking press with ring-serrated and counter-holding cylinders.

When fine-cutting workpieces, smooth, tear-free and tear-free cut surfaces can be produced and fracture surfaces, as are usually found in normal cutting, can be avoided. An essential feature of fineblanking is the embossing of a ring serration parallel to the cutting line on the lead frame side in order to prevent the material from re-flowing here; the ring spike is impressed by the ring spike cylinder. During the fineblanking process, the workpiece is pressed against the upper tool from below by a special sheet metal counterholder - hereinafter referred to as "counterholder".

State of the art

In conventional fineblanking presses, the force of the ring-toothed cylinder, which is arranged in the upper crosshead of the machine stand, counteracts the cutting force. The counter-holding cylinder, which is integrated in the ram or in the working piston, presses the workpiece against the upper part of the tool; the counterholder support force counteracts the cutting force. The counter force of the ring-toothed cylinder is up to 50% and that of the counter holder up to 25% of the work force. These opposing forces are converted into heat and reduced by the displacement principle during the working stroke additionally the cutting performance. In a conventional fineblanking press with, for example, 100 kW drive power, a cooling capacity of approximately 80 kW is installed, the cutting force of, for example, 4000 kN can be reduced by 3000 kN.

Object of the invention

In view of the previously known fineblanking presses with the unfavorable relationship between the total energy used and the actually usable cutting power, the invention is based on the problem of greatly reducing the energy losses in a fineblanking press. It must be ensured during the cutting process of the fineblanking press, the pressing in of the ring serration and the clamping of the workpiece against the upper tool.

Essence of the invention

According to the invention, the ring-toothed cylinder is integrated in a crossbar above the upper crosshead and is firmly connected to the plunger, so that it moves upwards in synchronism with the plunger. The counter-holding cylinder is arranged between the plunger and the lower crosshead of the stand. The piston of the ring-toothed cylinder is held in its lower position by a pressure-actuated support cylinder and thereby remains in constant contact with the pressure bolts of the upper tool. By attaching the support cylinder piston to the stand and integrating it into the ring-toothed cylinder piston, it can deflect upwards when the pressure is released during the working stroke. At the end of the working stroke, the pressure cylinder operated support cylinder pushes the ring-toothed piston into its lower basic position and at the same time strips off the ring-toothed punched grille.

The piston of the counter-holding cylinder is held in its upper position by a pressure cylinder actuated support cylinder, as a result of which it remains in constant contact with the pressure bolts of the lower tool. By attaching the support cylinder piston to the tappet and integrating it into the counter-holder cylinder piston, it can move downwards when the pressure is released during the working stroke. At the end of the working stroke, the pressure cylinder-operated support cylinder pushes the counter-holding piston into its upper basic position and at the same time pushes the fine blanking part into the tool space.

Due to the aforementioned arrangement, the power of the main drive can be fully used for cutting out the fine blanking part. This means that a fineblanking press is now available whose energy losses are greatly reduced. This is achieved in particular by the arrangement of the ring-serrated and counter-holding cylinder, which clamps the lead frame or the fine blanking part during the working stroke of the ram without executing a stroke. There is no relative movement between the ring-toothed cylinder and the tappet during the working stroke; the ring-toothed cylinder support forces are absorbed by the ram. The work force of the main drive is not reduced by the ring-toothed cylinder pressing force. At the same time, there is no relative movement between the counter-holding cylinder and the stand during the working stroke; the counterholder cylinder support forces are applied by the stand taken. The work force of the main drive is not reduced by the counter-holding cylinder contact pressure.

Brief description of the accompanying drawings.

1 is a sectional view of the fineblanking press with pretensioned, double-acting ring prongs, counterholders and working cylinders with the necessary control devices, the ring prong cylinder is firmly coupled to the ram via columns, in this embodiment there are center supports on the ring prongs and counterhold seen;

FIG. 2 shows an embodiment according to FIG. 1, but with single-acting cylinder systems, the ring spikes and counterhold are designed without center support;

3 shows an embodiment according to FIGS. 1 and 2, but with installation space adjustment, the working cylinder is arranged in the upper crosshead of the stand, the ring-toothed cylinder is integrated in the piston of the working cylinder;

FIG. 4 shows an embodiment according to FIG. 3, but with a single-acting cylinder;

5 shows an embodiment according to FIG. 3, as a pre-tensioned fineblanking press with double-acting working, ring-serrated and counter-holding cylinders;

6 shows a fineblanking press with a working cylinder arranged in the lower crosshead of the stand and a ring-toothed cylinder coupled via columns, the counter-holding cylinder is integrated in the piston of the working cylinder, in addition there is an installation space adjustment with a fixed stop;

FIG. 7 shows an embodiment according to FIG. 6, the ring-toothed cylinders are integrated on the columns in the cross member;

8 shows an embodiment according to FIG. 7, the ring-toothed cylinders are integrated on the columns in the ram;

9 shows an embodiment according to FIGS. 1 and 7, the ring-toothed cylinders are integrated on the columns in the crossmember, the working cylinders on the columns in the stand;

10 shows an embodiment according to FIG. 9, the ring-toothed cylinders are on the columns in the crossmember, the double-acting working cylinders on the columns in

Integrated stand;

11 shows an embodiment according to FIG. 1, the infeed and working stroke is generated by a mechanical toggle or eccentric drive;

12 shows an embodiment according to FIGS. 1, 2 and 3, the arrangement of the single-acting working cylinders takes place in the upper crosshead of the stand, in this embodiment an installation space adjustment is arranged below the plunger; 13 shows an embodiment according to FIG. 12, but with a double-acting, prestressed working cylinder;

14 shows an embodiment according to FIG. 3, but with central support of the ring prong and counter-holder part, and an installation space adjustment with a fixed stop, the working and ring prong cylinder is arranged in the crossmember, and the pressure medium-actuated support cylinder is located between the working and ring-toothed cylinder piston integrated, the infeed and return stroke is carried out by the counter-holder cylinder, the piston rod diameters were adjusted in such a way that the infeed stroke, the counter-holder contact pressure and the return stroke are carried out by differential switching, the upper crosshead is connected to the connecting elements Stand attached;

15 shows an embodiment according to FIG. 14, the traverse and the tappet are connected on both sides to a plate, they form a tappet which is elongated upwards, in addition guide elements are attached to the tappet and stand, the upper crosshead attached to the stand with fasteners;

16 shows an embodiment according to FIGS. 10 and 13, the double-acting working cylinders are in the upper one

Crosshead around the pillars, the ring spike cylinders arranged in the crossbeam around the pillars, the holes for the ring spike pressure bolts are not arranged around the center support, but are distributed in the upper crosshead, the upper one Crosshead is attached to the stand with fasteners;

17 shows a sectional illustration of a fineblanking press with hydraulically preloaded, double-acting working, ring-toothed and counter-holding cylinders; Two working cylinders, a ring-toothed cylinder and two stripping cylinders are arranged in the upper traverse; the cross member and the pusher plate are laterally connected to a plate and together form a pusher which is elongated upwards;

18 shows an embodiment according to FIG. 17, but with single-acting cylinders; and

19 shows an embodiment according to FIG. 17, but with a reversal of the movable and fixed machine components.

Practical examples

The invention will now be described with reference to the accompanying

Drawings explained in detail.

Figure 1

A solution is shown in which the columns 3 are firmly connected to the plunger 1. The columns 3 penetrate the stand 4 in the region of the upper crosshead and are firmly connected to the cross member 2 here. A double-acting ring serrated cylinder C is integrated in the traverse 2. Below the plunger 1 are the columns 3 with a paragraph that as Is formed 3.1 piston of the working cylinder A _^ seen The working cylinder A is made of the Zylindergena-_.se 5, which is integrated in Stander 4, and the piston 3.1, they c_lden the pressure medium-beta-saturated cylinder chamber 5.1. A cylinder B unit is arranged between the ram 1 and the upper crosshead of the stand 4; the hydraulic effective area of the piston 7 is the same size as the piston area 3.1. The counter-aged cylinder D is integrated below the plunger 1 in the lower crosshead of the stand 4.

The fineblanking press is shown here in the lower starting position. The ram 1 is moved upwards by the Schr.ellhuD cylinder G. During the delivery stroke, the piston 7 displaces the pressure medium from the cylinder space 6.1 of the cylinder B, the pressure medium is supplied via line 27.1.

Valve 26 and line 27 m the cylinder space 5.1 of Zylin¬ der A shifted.

During the infeed stroke of the plunger 1, the crossbeam 2 and the cylinder housing 8 of its integrated ring cylinder C syncnron are moved upwards. The piston 13 of the Rmgzacken- cylinder C remains in constant contact with the pressure pin 9, it is held by the piston 21 of the pressure medium cylinder E in this lower position. The piston 21 is connected to the stand 4 by means of connecting elements 23. As a result of the upward movement of the cylinder housing 8, the pressure medium from the cylinder space 15 has to be shifted into the cylinder space 12 via line 14.1, valve 16 and line 14. The piston 35 of the counter-holding cylinder D, the housing 30 of which is fastened to the stand 4, is connected to the plunger 1 by the piston 44 of the pressure medium-loaded cylinder F; it remains in constant contact with the pressure bolts 36 and moves upwards with the feed movement of the plunger 1. The piston 44 is firmly connected to the plunger 1 via connecting elements 46. Due to the upward movement of the piston 33, the pressure medium is shifted from the cylinder space 39 via line 37, valve 38 and line 37.1 into the cylinder space 34.

When switching from the delivery stroke to the working stroke, the valves 26, 16, 38, 22 and 43 are switched from switch position "0" to switch position "1". In this case, the force of the cylinder A, which remains connected to the pressure medium source 40, takes effect immediately, since the cylinder space 6.1 of the cylinder B is connected to the tank via the valve 26.

The contact force of the ring-toothed cylinder C also takes effect immediately after the valve 16 has been switched over, since the cylinder chamber 12 remains connected to the pressure medium source 18 and the cylinder chamber 15 is connected to the tank 17 via the valve 16. The contact pressure is transmitted via the pressure bolts 9 into the fineblanking tool for pressing in the ring-toothed contour. The ring-toothed cylinder support force is passed from the housing 8 into the cross member 2 and from here via the pillars 3 into the plunger 1. During the working stroke, there is no relative movement between ring-toothed cylinder C with piston 13 and plunger 1. The worker of the The main drive is not reduced by the ring spike contact pressure.

The piston 21 of the cylinder E is relieved of pressure at the beginning of the working stroke via the valve 22 switch position "1", the piston 13 can be displaced upwards.

The pressing force of the counter-holding cylinder D also takes effect immediately after the valve 38 has been switched over, since the cylinder space 34 remains connected to the pressure medium source 40 and the cylinder space 39 is connected to the tank 41 via the valve 38. The contact pressure is transferred via the pressure bolts 36 into the fineblanking tool for pressing on the workpiece. The counter-holder cylinder support force is transmitted from the housing 30 into the stand 4. During the working stroke, there is no relative movement between the counter-holding cylinder D and the workpiece in the tool.

The piston 44 of cylinder F is relieved of pressure at the beginning of the working stroke via valve 43 switch position "1"; the piston 35 moves downwards relative to the working stroke of the ram 1. The work force of the main drive is not reduced by the counter pressure.

At the end of the working stroke, the valves 26, 16, 38, 22 and 43 are switched from switch position "1" to switch position "0".

The cylinder space 6.1 of the cylinder B is connected to the pressure medium source 40 via the valve 26 and generates one _G egenkraft to the fluid-operated cylinder A, the Ar¬ beitskraft is canceled.

The cylinder space 15 of the ring-toothed cylinder C is connected to the pressure medium source 18 via the valve 16 and generates a counterforce to the cylinder space 12, the ring-toothed force is released. The support cylinder E is pressurized by switching valve 22 and pushes the piston 13 into its lower starting position; in this case the lead frame is ejected via the pressure bolts 9.

The cylinder space 39 of the counter-holding cylinder D is connected to the pressure medium source 40 via the valve 38 and generates a counterforce to the cylinder space 34; the counter-holding force is released. The support cylinder F is pressurized by switching valve 43 and pushes the piston 35 into its upper starting position, in this case the fine stamping part is ejected via the pressure bolt 36. The ram 1 is moved downward into the basic position of the machine by the rapid stroke cylinder G, the fine blanking cycle is ended.

Figure 2

The fineblanking press with single-acting cylinder systems is shown here. The arrangement of the ring-toothed cylinder C2 in the crossmember 2 and the counter-holding cylinder D2 between the plunger 1 and the stand 4 corresponds to FIG. 1

Fineblanking press is shown in the starting position.

At the start of the fineblanking cycle, the ram 1 is moved upwards by the rapid stroke cylinder G. During the

Delivery strokes are pressure medium via the suction valves 2.28, 2.15 and 2.39 sucked into the main, ring prong and counter holding cylinder. At the start of the working stroke, the valves 2.16, 2.26, 2.38 are switched from switch position "0" to "1". Cylinder rooms 2.51, 2.12 and 2.33 are pressurized. The working cylinder A2 generates the

Punching force and moves the ram up. At the same time, the piston 2.13 of the ring prong cylinder C2 presses the ring prong contour into the lead frame via the pressure bolts 9. The ring-toothed cylinder support force is passed from the housing 2.8 into the cross member 2 and from here via the columns 3 into the plunger 1. During the working stroke, there is no relative movement between ring-toothed cylinder C with piston 2.13 and plunger 1. The work force of the main drive is not reduced by the ring spike pressure.

The cylinder space 2.33 of the counter-holding cylinder D2 is pressurized at the start of the working stroke. The cylinder housing 2.30, which is connected to the pressure bolt 2.36 and the plunger 1 via the support cylinder F, transmits the contact pressure to the workpiece via the pressure bolts 2.36. The counterholder support force is transferred into the stand 4 via the piston 2.31. During the working stroke there is no relative movement between the counter-holding cylinder D2 and the workpiece. The counter cylinder support force does not reduce the work force of the master cylinder.

At the end of the working stroke, valves 2.16.2.22.2.39 and 2.43 are switched from switch position "1" to "0" and valve 2.26 from switch position "1" to "2". The cylinders A2, C2 and D2 are depressurized, the support cylinders E and F are pressurized. The support cylinder E pushes the punching grid and the support cylinder F the workpiece, as described in Fig. 1, out.

FIG. 3 A fineblanking press is shown in a similar design to that described in FIGS. 1 and 2. The working cylinder A3 is arranged in the upper crosshead of the stand 4. The area of the piston 3.5.2 is approximately the same size as the four areas of the piston 7. In the starting position and during the feed and return stroke movement, the cylinder spaces 6.1 and 3.5.1 are pressurized. The force of the cylinder A3 is the same as the forces of the four cylinders B3.

The ring-toothed cylinder C3 is integrated in the piston 3.5.2 of the working cylinder A3. The active surfaces 3.12 and 3.15 correspond to the surfaces 12 and 15 according to FIG. 1. The course of the working cycle can be seen from the description according to FIG. 1. The fineblanking press is provided with an installation space adjustment 3.6, which is arranged below the ram 1. The columns 3 are provided with a thread 3.6.1 at the lower end. The threaded nut 3.7 is rotatably fastened to the plunger 1 with fastening elements 3.7.1. The threaded nuts 3.7 are provided with teeth for chain or toothed belt drives. The four nuts 3.7 are adjusted synchronously via a chain or a toothed belt. The adjustment can be carried out in such a way that the stop surface 7.1 of the piston 7 hits the cylinder housing 6 at the end of the working stroke when the fineblanking tools are of different heights. Figure 4

The example here shows a fineblanking press with single-acting cylinder systems. The mode of operation and operation is similar to that described in FIG. 2, the cylinder arrangement is similar to that shown in FIG. 3.

Figure 5

Shown is a fineblanking press, the operation of which was described in FIGS. 1 and 3. The four preload cylinders B and B3 (FIGS. 1, 3) are replaced by a cylinder B5. The cylinder B5 is arranged between the stand 4 and a second crossbeam 5.2. An installation space adjustment 3.6, as described in FIG. 3, is arranged below the cross member 5.2.

Figure 6

This embodiment of the fineblanking press differs from the embodiment according to FIG. 1 in that the four working cylinders A are replaced by a cylinder A6 with installation space adjustment. The counter-holding cylinder D6 is integrated in the piston 6.6 of the working cylinder A6. The mode of operation is described in FIG. 2 for the main drive and in FIG. 1 for the ring-toothed and counter-holding cylinder.

Figure 7

The structure of the fineblanking press shown here is identical to that of FIG. 6, only the ring-toothed cylinder C6 is replaced by four cylinders C7, which are arranged in the upper region of the columns 3. The mode of operation of the ring-toothed cylinders is described in FIG. 1. Figure 3

Now the ring serrated cylinders C8 have been integrated into the plunger 1 at the lower end of the columns 3. For the mode of operation, see Fig. 1.

Figure 9

Now the working and serrated cylinders are arranged on the columns 3 of the fineblanking press; an installation space adjustment, as shown in FIG. 3, can alternatively be installed. The ring-toothed cylinders C9 are designed as shown in FIG. 7, and the working cylinders A9 correspond to the embodiment according to FIGS. 1 and 2. For the mode of operation, see again in FIG. 1.

In this embodiment, a double-acting working cylinder A10 is arranged in the lower crosshead of the stand 4. The method of operation corresponds to that of FIG. 1.

Figure 11

A fineblanking press with a mechanical main drive is shown. The main drive can, as shown, be designed as an eccentric or, as not shown, as a toggle lever drive. The delivery, working and return stroke of the ram 1 is carried out by the mechanical drive. The mode of operation of the ring-tooth cli and counter-holding cylinder DU corresponds to the description according to FIG. 1. An installation space adjustment, as shown in FIG. 4, allows the use of tools with different heights. The The work force of the mechanical main drive is not reduced by the ring spike and counter-pressure.

Figure 12 A single-acting cylinder A12 is in the upper

Arranged crosshead of the stand 4, the operation is described in Fig. 2. Due to the arrangement of the working cylinder A12 in the upper crosshead, the working force is passed directly from the piston 12.4 via the columns 3 into the plunger 1. The stand 4 is not loaded by the worker and only needs to absorb the supporting forces of the counter-holder. A guide 12.1 can also be attached to the plunger 1.

Figure 13

The fine blanking press shown is identical in construction to the embodiment according to FIG. 12, only the working cylinder is double-acting. For the mode of operation, see Fig. 1.

Figure 14

In the compact embodiment, a working cylinder A14, a ring prong cylinder C14, a supporting cylinder E14 and an installation space adjustment with a fixed stop are integrated in a cylinder piston unit. As in FIGS. 12 and 13, the stand 4 is not used by the worker. Via the valve 14.38, the feed and return stroke of the ram is additionally carried out by the counter-holding cylinder. The piston rod diameters were adjusted in such a way that the delivery stroke, the counter-holding pressure and the return stroke are carried out by differential switching. With position "0" of valve 14.38, all connections are interrupted and the plunger is located yourself in the UT position. In position "1", the cylinder spaces 14.39 with 14.34 are connected to the pressure medium source. The differential surface 14.40 pushes the piston including the plunger 1 and crossbar 2 upwards. At the start of the working stroke, the valve 14.38 is switched to position "2", the cylinder space 14.39 is relieved of pressure, the cylinder space 14.34 remains connected to the pressure medium source and thus generates the counterpressure pressure. The return stroke is initiated by position "3", the cylinder space 14.34 being connected to the tank and the cylinder space 13.39 being connected to the pressure medium source. In UT it is switched to position "0".

Figure 15

According to the embodiment variant according to FIG. 14, the cross member 2 and the plunger 1 are connected on both sides to a plate 15.2; they form a plunger elongated upwards. In addition, guide elements 15.6 and 15.8 are attached to the plunger 1 and stand 4. The upper crosshead 4.1 is fastened to the stand 4 with connecting elements, and the columns 3 from FIG. 14 are replaced by the plates 15.1. The stand 4 is not claimed by the force of the working cylinder A.

FIG. 16 In this embodiment according to FIGS. 10 and 13, the double-acting working cylinders A16 in the upper crosshead 4.1 are arranged around the columns 3 and the ring-toothed cylinders C16 in the cross member 2 are also arranged around the columns 3. The conventional center support is omitted. The holes 16.10 for the ring serrated pressure bolts 16.9 are not arranged around the middle, but are distributed in the upper transverse 4.1 at all. The stand 4 is not stressed by the force of the working cylinder A16.

FIG. 17 shows an embodiment in which the cross member 2 is designed as a cylinder housing. Two working cylinders A17, a ring-toothed cylinder C17 and two stripping cylinders E17 are integrated in the traverse 2. The two double-acting working cylinders A17 are arranged laterally in the cross member 2. The lower piston A17.2 forms together with the cylinder housing 2 (here designed as a traverse) the lower cylinder space A17.3. The upper cylinder space A17.4 is formed by the cylinder housing 2 and the upper piston rod A17.5. The two lower piston rods A17.2 are firmly connected to the upper crosshead 4.1 via connecting elements A17.9. The two upper piston rods A17.5 are connected to a plate which is designed as a hydraulic distributor block A17.10. The double-acting ring-tooth cylinder C17 is arranged in the middle between the working cylinders A17. The lower piston C17.1 forms together with the

Cylinder housing 2 the lower cylinder chamber C17.2. The upper cylinder chamber C17.4 is formed by the cylinder housing 2 and the upper piston rod C17.5. A plate E17.4 is fastened to the ring-toothed cylinder piston C17.1, on which the pressure bolts 9 are supported. The scraper cylinders E17 are integrated in the piston A17.2. The two support cylinders E17 arranged on the side can hydraulically compensate for eccentric loads on the ring spike forces.

The ram plate 1 forms with the plates 3 'and the cross member 2 the press ram. The counter-holding cylinder is D17 arranged below the plunger plate 1 in the lower crosshead of the stand 4. The two support cylinders F17 arranged on the side can hydraulically compensate for eccentric loads on the counter-holding forces. The discharge cylinders F17 are attached to the plunger plate 1. The stand 4 is not stressed by the working force of the working cylinders A17.

FIG. 18 In contrast to the fineblanking press according to FIG. 17, the working, ring-serrated and counter-holding cylinders are single-acting here. For the mode of operation of the press, see FIGS. 2 and 17.

Figure 19

A fineblanking press, as described in FIG. 17, is shown, wherein the movable and fixed machine components have been reversed. The ram plate 1 'is firmly connected to the machine stand, and the function of the press ram is taken over by the movable ram 4.1'. The ram plate 1 ', the crossbeam A19.1 and the plates 3' are firmly connected to one another, together they form the stand of the fineblanking press. The plates 3 'are extended downwards via the ram plates 1' and form the foot of the stand in the region 3.2 '. With the traverse A19.1, the housing of the two working cylinders A19 and the housing of the ring-toothed cylinder C19 are firmly connected to the stand. The two lower piston rods A19.2 of the working cylinders A19 are fastened to the movable plunger 4.1 'by connecting elements A19.9. The piston rod C19.1 of the serrated cylinder C19 is via the plate E19.4 by hydraulic coupling of the supporting cylinder E19 97/35675 PCMB97 / 00312

- 20 -

connected with the plunger 4.1 '. The cylinder housing D19.6 of the counter-holding cylinder D19 is firmly connected below the ram plate 1 'to the movably arranged crossbar D19.9. The ram 4.1 'and the crossbar D19.9 are connected to one another by the plates 4' and connecting elements D19.8. Columns could also be used instead of the plates 3 ', 4'.

The feed cylinders G19 are attached with their cylinder housings to the plates 3 'with the piston rods to the plunger 4.1'. When the tool is closed, the plunger 4.1 'and the housing D19.6 of the counter-holding cylinder D19 which is firmly connected to it are moved downward via the feed cylinder G19. During this feed movement, there is a relative movement between the piston rods and the cylinder housings of the working cylinders A19, the ring-toothed cylinder C19 and the counter-holding cylinder D19. The pressure medium is shifted from the upper cylinder spaces into the lower cylinder spaces. The operation of the double-acting cylinders is described in Fig. 1.

Claims

claims

1. Fineblanking press with hydraulically or mechanically driven ram, each with at least one hydraulic ring prong and counter-holder cylinder, the support plates on the ring prongs and counter-holder being partially designed with center supports, characterized in that a) the at least one ring prong cylinder (C) above of the upper crosshead (4.1) of the stand (4) is integrated in a cross member (2) and is firmly connected to the plunger (1), so that the cross member (2) moves upwards in synchronism with the plunger (1) emotional; b) the at least one counter-holding cylinder (D) is arranged between the plunger (1) and the lower crosshead of the stand (4); c) the piston (13) of the ring-toothed cylinder (C) is held in its lower position by a pressure medium-actuated support cylinder (E) and thereby remains in constant contact with the pressure bolts (9) of the upper tool; d) by the attachment (23) of the support cylinder piston (E) to the stand (4) and the integration in the ring-toothed cylinder piston (13), which deflects upwards when the pressure is released during the working stroke; e) at the end of the working stroke, the pressure-actuated support cylinder (E) moves the ring-toothed piston (13) into its lower one

Pushes the basic position and at the same time strips off the ring-serrated lead frame; f) the piston (35) of the counter-holding cylinder (D) through a pressure-actuated support cylinder (F) in its upper one Is held in position, whereby it remains in constant contact with the pressure bolts (36) of the lower tool; g) through the fastening (46) of the support cylinder piston (44) to the tappet (1) and the integration in the counter-holding cylinder piston (35), which deflects downwards when the pressure is released during the working stroke; and h) at the end of the working stroke, the pressure cylinder-actuated support cylinder (F) pushes the counter-holding piston (35) into its upper basic position and at the same time pushes the fine blanking part into the tool space.

2. Fineblanking press according to claim 1, characterized ge indicates that a) the ram (1) by at least two columns (3) which penetrate the stand (4) upwards, is firmly connected to the cross member (2); b) the columns (3) are attached to the plunger (1) via connecting elements (3.4), a second shoulder of the columns (3) below the plunger (1) being designed as a piston (3.1) and a cylinder housing (5 ) surrounds this piston (3.1) and forms the pressure-operated cylinder chamber (5.1) of the working cylinder (A), which is integrated in the stator (4); c) a cylinder piston unit (B) is arranged between the plunger (1) and the crossbeam (2) on the columns (3), the cylinder piston unit (B) consisting of the cylinder housing (6), the columns (3) being tubular in the upper region um¬ closes, and there is an annular piston (7) which is connected to the column (3); d) the piston (7) has a shoulder (7.1) in the lower region with an annular diameter enlargement, wherein the paragraph (7.1) serves as a fixed stop for the working stroke and the hydraulic effective surfaces of the annular piston (7) and the piston (3.1) are of the same size; e) the ring spike cylinder (C) and the counter holder cylinder (D) have at least the stroke length of the working cylinder (A), - f) the ring spike cylinder (C) and the counter holder cylinder (D) are hydraulically preloaded cylinders, so that the

Ring-toothed cylinder contact pressure and the counter-holder cylinder contact pressure become effective immediately through pressure relief.

3. Fineblanking press according to claim 1 characterized ge. that the single-acting pressure medium cylinders, namely the ring-toothed cylinders (C2) and / or the

Counter-holding cylinders (D2) and / or the working cylinders (A2) can be filled with pressure medium during the feed movement, which is preferably done via suction valves or shut-off valves from an unpressurized or pressurized reservoir.

4. Fineblanking press according to claim 1, characterized ge indicates. that a) the working cylinder (A, A3) is arranged in the upper crosshead (4.1) of the stand (4), so that the side parts of the

Stand (4) from the working cylinder (A3) remain unloaded, where b) the single- or double-acting ring prong cylinder

(C, C3) can be integrated in the piston (3.5.2) of the working cylinder (A3); c) the single-acting cylinder (A3) at least one counteracting cylinder (B3) is assigned, and d) the columns (3) in the lower area are each connected to the plunger (1) by means of a 'creation device (3.6).

5. Fineblanking press according to claim 1, characterized in that a) the columns (3) are connected in the lower region via a respective adjusting device (3.6) to a second cross member (5.2), and between the cross member (5.2) and stand (4) a cylinder piston unit (B5) is arranged; and b) the hydraulic effective surfaces of the working cylinder (A5) and the counteracting cylinder (B5) are large.

6. fineblanking press according to claim 1, characterized ge indicates that a) a working cylinder (A6) is arranged in the lower region of the stand (4); b) the working cylinder (A6) is connected to the stand (4) via an adjusting device (6.5.3); and c) a pressure-medium-actuated counter-holding cylinder (D6) is arranged in the piston (6.6) of the working cylinder (A6).

7. Fineblanking press according to claim 6, character- ized in that a) in the upper region of the columns (3) one ring toothed cylinder (C7) is arranged; b) the columns (3) in the upper region as piston rods (7.10,7.13) and as pistons (7.11) are formed, whereby c) A hydraulic connection is created between the ram (1) and the crossbeam (2).

8. Fineblanking press according to claim 6, characterized in that a) a ring-toothed cylinder (C8) is arranged in the lower region of the columns (3); b) the columns (3) in the lower area are designed as piston rods (8.8,8.10) and as pistons (8.11), whereby c) a hydraulic connection is created between the plunger (1) and crossbar (2).

9. Fineblanking press according to claim 7, characterized in that a) in the lower region of the columns (3) per column (3) a single- or double-acting working cylinder (A9, A10) is arranged; and b) the columns (3) are designed as pistons (9.3.1, 10.4) in the lower region.

10. fineblanking press according to claim 1, characterized ge indicates that a) the empty part, work and return stroke movement is actuated by a mechanical drive (11.3.1 to 11.3.4); b) the ring-toothed and counter-holding cylinders (C11, D11) are hydraulic; and c) the mechanical drive (11.3.1 to 11.3.4) is arranged between the upper crosshead (4.1) of the stand (4) and crossbar (2) or between the lower crosshead of the stand (4) and plunger (1).

11. Fineblanking press according to claim 1, characterized ge indicates that a) the columns (3) in the region of the upper crosshead of the stand (4) are each designed as single- or double-acting working cylinders (A12, A13); and b) a single-acting or double-acting ring-toothed cylinder (C16) can be arranged on the columns (3) in the area of the crossmember (2).

12. Fineblanking press according to claim 1, characterized ge indicates that a) the working cylinder (A14), the ring-point cylinder (C14), the support cylinder (E14) and the installation space adjustment (H14) are arranged in the cross member (2); b) the cross member (2) is firmly connected to the plunger (1) via columns (3); or c) the cross member (2) and the plunger (1) with plates (15.1) are firmly connected to one another.

13. fineblanking press according to claim 1, characterized ge indicates that a) in the crossmember (2) two single- or double-acting working cylinders (A17, A18), a single- or double-acting ring-toothed cylinder (C17, C18) and two Stütz¬ cylinders (E17) are arranged; b) the cross member (2) serves as a cylinder housing for the ring-toothed cylinder (C17) and the working cylinder (A17); c) in the lower area, the pistons (A17.2) with connecting elements (A17.9) are firmly connected to the upper crosshead (4.1) of the stand (4); d) the ring-toothed cylinder (C17) is arranged between the two working cylinders (A17, A18) in the crossmember (2); e) the lower piston (C17.1) of the ring-toothed cylinder (C17) and the pistons (E17.1) of the support cylinders (E17) are connected together with a plate (E17.4); f) the support cylinders (E17) are integrated in the lower piston (A17.2) of the working cylinder (A17); g) occurring eccentric loads on the ring-toothed cylinder (C17) can be compensated hydraulically via the cylinders (E17) and valves (E17.3); h) the traverse (2) and the ram plate (1) with plates (3 ¹ ) are firmly connected to one another via connecting elements (J17.3, J17.4) and together form the press ram; i) guides (J17.1) are fastened to the stand (4) in the upper and lower region of the press ram; j) adjustable, interconnected stops (H17) are arranged on the ram plate (1), which limit the ram stroke upwards and serve as a fixed stop; k) the support cylinders (F17) are attached to the underside of the ram plate (1); 1) the upper pistons (D17.7) of the counter-holding cylinder (D17) and the pistons (F17.1) of the support cylinders (F17) are connected together with a plate (F17.4); m) occurring eccentric loads on the counter-holding cylinder (D17) can be compensated hydraulically via the support cylinders (F17) and valves (F17.3); and n) eccentric loads occurring during the working stroke can be hydraulically compensated via the working cylinders (A17) and the valves (A17.8).

14. Fineblanking press with hydraulically or mechanically driven ram, each with at least one hydraulic single- or double-acting ring prong and counter-holder cylinder, the support plates on the ring prongs and counter-holder being partially designed with center supports, characterized in that a) the pusher plate (1 ') and the traverse (A19.1) are firmly connected to each other by means of plates (3 ¹ ) or columns, they together form the stand of the fineblanking press; b) with the crossmember (A19.1) the housing of the at least one working cylinder (A19) and the housing of the ring-toothed cylinder (C19) is firmly connected to the stand; c) the lower piston rods (A19.2) of the working cylinders (A19) are fastened to the movable upper plunger (4.1 ') by connecting elements (A19.9) and the piston rod (C19.1) of the ring-toothed cylinder (C19) via the plate (E19 .4) is connected to the plunger (4.1 ') by hydraulic coupling of the support cylinder (E19); d) the cylinder housing (D19.6) of the counter-holding cylinder (D19) below the plunger plate (l ¹ ) is firmly connected to the movably arranged traverse (D19.9) and the upper plunger (4.1 ') and the traverse (D19.9) are connected to each other by the plates (4 ') or columns; e) the feed cylinders (G19) with their cylinder housings are attached to the plates (3 ¹ ) with the piston rods on the upper plunger (4.1 '), so that when the tool is closed via the feed cylinder (G19) the upper plunger (4.1' ) and the housing (D19.6) of the counter-holding cylinder (D19) which is firmly connected to it are moved downwards; f) the piston (C19.1) of the ring-toothed cylinder (C19) is held in its lower position by at least one pressure-actuated support cylinder (E19) and thereby remains in constant contact with the pressure bolts (9) of the upper tool; g) the support cylinders (E19) can be integrated in the lower piston (A19.2) of the working cylinder (A19); h) occurring eccentric loads on the ring-toothed cylinder (C19) can be hydraulically compensated via the cylinders (E19); i) (l ¹⁾ adjustable to each other ver¬ Thematic stops (H19) are disposed on the ram plate, the hub of the ram height limit downwardly and serve as a fixed stop; j) the support cylinders (F19) are fastened to the underside of the ram plate (l ¹ ); k) the upper pistons (D19.7) of the counter-holding cylinder (D19) and the pistons (F19.1) of the support cylinders (F19) are connected together with a plate (F19.4);

1) occurring eccentric loads on the counter-holding cylinder (D19) can be compensated hydraulically via the support cylinders (F19) and valves; and m) eccentric loads occurring during the working stroke can be hydraulically compensated for via the working cylinders (A19).