EP1193046A1 - Method for controlling the mutual angular position between the slide and the clamping table of a punch press and punch press for carrying out this method - Google Patents

Abstract

Process for controlling the angle adjustment between a ram (34) and a tensioning table (39) of a stamping press comprises controlling the force of the ram and/or tensioning table during an operating state in a skew position to achieve the angle adjustment. During the effect of the force the parallelism is achieved. Preferred Features: The size and site of attack of the force is calculated before operation of the press. The angle adjustment is determined periodically.

Description

The present invention relates to a method to control the mutual angular position between a ram and a clamping table of a punch press, which ram with an upper tool part and which clamping table with a lower tool part Sequential cutting tool for processing a step by step band-shaped workpiece advanced by the punch press are connected with which processing during the action of the secondary cutting tool on the workpiece and the following action of a force on the Pestle and on the worktop an at least approximate Parallelism between the ram and the clamping table must be present. It continues to affect one Stamping press to carry out the process, which Punch press one press frame, one in the press frame guided ram and one in the press frame Clamping table, which plunger for connection with an upper tool part and which clamping table for Connection with a lower tool part of a sequential cutting tool are trained for editing one step by step through the punch press, band-shaped work piece is determined which Punching press a device for adjusting the height position of the plunger and / or a device for adjusting the position of the clamping table.

Many products made by punch presses, produced in particular by means of follow-up cutting tools must be extremely precise and of the highest quality be trained. Such products are, for example very fine parts, also semi-finished products, for electronic devices or telecommunications equipment.

Furthermore, the individual tool parts are like Stamps, dies, embossing tools, very expensive, precisely manufactured Products, on the one hand, the wear and tear must be kept as small as possible, and on the other hand remain extremely precisely aligned with one another to work properly. These tool parts are partly with the upper tool and partly with the lower tool of, for example, a subsequent cutting tool connected, the upper tool, as is known is connected to the ram and the lower tool with connected to the clamping table of a respective punch press is. This means that the precise alignment mentioned above by appropriately aligning the ram and Clamping table must be done. The pestle leads during operation from vertical strokes, but is over various power transmission elements such as arms, levers, Handlebars etc. connected to the press drive, the one Can have a crankshaft or an eccentric shaft, which mentioned components stored in bearings and in guide devices are led.

For the sake of the manufacturing precision mentioned and rapid wear of the tool parts to be avoided the plunger and the work table must be continuous and especially with the first working stroke of a new one fed strip-shaped workpiece exactly parallel to each other be aligned. However, the power transmission links exist of the pestle, even if it is very are rigid, from a fundamentally elastic Material, e.g. Steel, so that when subjected to force even if only the smallest, but still noticeable elastic Deformations occur. Each camp also points, each Perform a little game. These facts lead to that the ram is relative to the clamping table can orientate wrong, so that the disadvantages mentioned occur because in the inclined position of the ram Tool parts are not exactly aligned with each other.

An inclination of the ram relative to Clamping table, so that a parallelism between ram and worktop is no longer available, can now during the continuous punching operation of a punch press arise. Every machining operation on a workpiece creates one on the ram and on the clamping table acting force. Once that force is not on the center of the ram and the clamping table, so is an eccentric force, one arises, though no matter how small, misalignment of the ram relative to Clamping table, the point of attack being on the ram acting eccentric force the center of rotation of the ram. A follow cut tool obviously points a large number of individual tool parts on, each of which one in the operation of the punching machine Exerts force on the pestle. These powers are as Force components of a total force to be considered acts on the ram, and although this is from the toolmakers is striven for, it is obviously extremely difficult, the tool parts and work steps like this to distribute that along a follow-up cutting tool this total force exactly in the center of the ram on it acts.

The so-called punching is the off-center Load on the ram, which causes the Stössels caused, much more pronounced. At the gradual insertion of a new band-shaped workpiece acts in the punching machine in a first processing step only a first tool part on the workpiece, and that at a front end portion thereof, which part of the tool is obviously at one end Introducer of the elongated follow-up cutting tool is arranged so that an extreme eccentric load and thus the ram is skewed. at the next processing step then moves the place of action against the center of the ram. However, since working stroke to working stroke more tool parts to act on the gradually moving forward Work on the workpiece, the value of the off-center increases Force. After the front end at the approximate center the plunger has been moved past, the value drops the eccentric force, but the total Force that acts on the ram obviously increases. As soon as an entire length of tape in the punch press is arranged, the value of the eccentric force (Ideally) zero, where the value of the total force is Maximum reached.

Depending on the size and degree of impact The ram takes changing eccentric force Misalignments relative to the work table at and arises (ideally) when the value of total Force reached the maximum mentioned and not off-center acts on the ram, finally parallel to the work table on.

As is well known, it is necessary that already at the first working stroke of the punch press, at Stamping worked with extremely precise precision should be.

In the previously known punch presses an inclination of the ram and thus one non-parallel angular position between the plunger and the clamping table in particular with an eccentric load inevitable when punching.

The invention seeks to remedy this. The Invention as characterized in the claims solves the Task, a method of controlling a plunger Punch press and a punch press for carrying out the To create procedures in which the parallelism between the pestle and the worktable during exposure an eccentric force is ensured.

The method according to the invention is thereby characterized that for an operating state with a off-center on the ram and on the clamping table the force of the ram and / or the clamping table during an operating state not exposed to this force in an inclined position to reach one mutual angular position is controlled, so that during the action of the eccentric force the at least approximated parallelism is achieved.

The punch press to carry out the process is characterized in that the device for Adjustment of the height of the ram several height adjustment units and / or the device for position adjustment of the clamping table several position adjustment units has that each height adjustment unit and each position adjustment unit has its own actuator, and that the punch press has a control device, by means of which the actuator can be operated independently are.

The advantages achieved by the invention are essentially to be seen in the fact that when it occurs one off-center on the ram and the clamping table the parallelism between the plunger and the worktop is retained and thus the Precision and quality of the manufactured products are not affected will and no further major wear the tool parts takes place.

Fig. 1 zeigt einen Schnitt durch eine Stanzpresse, und

Fig. 2 eine graphische Darstellung eines Betriebes mit einer aussermittigen Kraft ohne gesteuerte Schrägstellung des Stössels,

Fig. 3 eine graphische Darstellung eines Betriebes mit einer aussermittigen Kraft mit einer gesteuerten Schrägstellung des Stössels, und

Fig. 4 ein Diagramm, in welchem die Änderungen der Grösse und der Ort der auf den Stössel einwirkenden Kraft während dem Anstanzen dargestellt ist.

In the following, the invention is explained in more detail, for example, with reference to drawings showing the embodiments.

Fig. 1 shows a section through a punch press, and

2 is a graphic representation of an operation with an eccentric force without controlled inclination of the ram,

Fig. 3 is a graphical representation of an operation with an eccentric force with a controlled inclination of the ram, and

Fig. 4 is a diagram in which the changes in size and the location of the force acting on the ram is shown during the punching.

The embodiment described below refers to a cross-shaft two-point punch press. That means the band-shaped workpiece to be machined becomes in a direction transverse to the longitudinal axis of the drive shaft the punch press advanced and the ram is driven by two pressure columns.

However, the invention also includes longitudinal shaft punch presses, in which the band-shaped to be processed Workpiece in a direction parallel to the longitudinal axis the drive shaft of the punch press becomes.

The invention also includes four-point punch presses, where the ram with four pressure columns is driven. That means the pestle is not only in relation to the direction of the advanced band-shaped Workpiece, that is relative to the longitudinal direction of the Workpiece can be tilted. He can with these Punching presses also inclined diagonally , that is, if the point of attack of the eccentric force not with the longitudinal center line of the Pestle coincides, but is arranged next to it on the side is.

Further is known and the invention encompasses this training also that the position of the clamping table, i.e. whose height is changed can. This means that the invention is not just one Inclination of the ram includes, but also a Inclination of the worktop, and obvious also a simultaneous inclination of both the Ram and the clamping table.

The embodiment described below is now on a cross-shaft punch press with two Pressure columns directed.

The punch press shown in FIG. 1 has a press frame 1 on the top through a cover plate 2 is completed.

The press drive is generally with the reference number 3 indicated. For example, it has one Pulley driven by a motor via V-belts on, by means of a known clutch braking device 4, which is shown in dashed lines with the Drive shaft 5 of the punch press is connected. The drive shaft 5 is stored in the press frame 1. On one The eccentric section 6 of the drive shaft 5 is the connecting rod 7 stored. The connecting rod 7 is connected to a connecting rod bolt 8 articulated a sliding block 9, which is guided in a backdrop 10 is. There is also a tab 54 on the connecting rod bolt 8 articulated, which carries a pivot pin 11.

There are two double-armed on these pivot pins 11 Articulated levers 12, 13, which are mounted in the press frame 1 are. On these double-armed levers 12, 13 are one-armed lever 14, 15 articulated. In their of the double-armed Levers 12, 13 distal ends are the one-armed Levers 14, 15 on pivot pins 16, 17 on tabs 18, 19 articulated, which are connected to spindle nuts 20, 21 are. These spindle nuts 20, 21 sit on threaded spindles 22, 23, the bottom with a drive gear 24, 25 are equipped.

The reference numerals 26, 27 denote frequency-controlled Motors and the associated controls are generally designated by the reference numerals 28, 29. The frequency-controlled motors 26, 27 are not shown Worm wheels in drive connection with the Drive gears 24, 25 of the threaded spindles 22, 23.

There are pressure columns on the one-armed levers 14, 15 30, 31 articulated via bolts 45, 46, which pressure columns 30, 31 at their lower ends via bolts 32, 33 are hinged to a plunger 34. This pestle 34 is, as is generally known, for receiving the upper tool 57 determined a follow-up cutting tool.

The plunger 34 has guide columns 35, 36 connected via column guides 37, 38 in the press frame 1 are performed.

Under the ram 34 is on the press frame 1 supported mounting table 39 for receiving the Lower tool 58 of a sequential cutting tool is formed.

The connecting rod 7 has an upper extension 40 on which transmission rods 41, 42 articulated are known to the mass balance weights 43, 44 Execution are articulated.

The tabs and levers described above are, as is well known, not to be considered as one-piece structures, but from multi-part, parallel to each other arranged individual parts assembled, if necessary are mounted on a common pivot pin and fork-shaped in connection with neighboring components stand.

The components that can be moved by the motors 26, 27 18-24 form together with the controls 28, 29 two ram height adjustment units, by means of which general, as known to those skilled in the art, the ram height, i.e. the respective distance of the plunger 34 in each position the stroke of the clamping table 39 can be adjusted. The For the sake of completeness, height adjustment devices are also 55, 56 for the clamping table 39 is shown schematically.

These height adjustment units from Stössel 34 and also from the worktop 39 can be completely independent controlled and operated from each other or synchronously become. This is in contrast to the known designs, especially for rams where the ram adjustment units mechanical, e.g. over a wave with each other are connected.

Reference is now made to FIG. 2, in which the components necessary for understanding the invention the punch press of Fig. 1 together with acting Forces are drawn in a highly simplified manner.

The are represented by simple lines Clamping table 39 and the ram 34. Next are the Pivots 16, 17, the pressure columns 30, 31 with the lower Bolts 32, 33 and the upper bolts 45, 46, as well the guide columns 35, 36 and the column guides 37, 38 located. The vertical center line 47 through the Punching press is shown in dash-dot lines.

To simplify the following Description and in particular the figures a shift only between the guide columns 35, 36 and Column guides 37, 38 shown. For further shifts, e.g. in bearings through the bearing play and also (elastic) Deformation of components is not special received. The deformations are representative reduced to the pressure columns 30, 31 of FIGS. 2 and 3.

In operation of the punch press, i.e. if the Tappet 34, i.e. the associated upper tool, is being machined acts on a band-shaped workpiece, acts the force F1 on the bolt 45 from the press drive, what force on the pressure column 30 and the bolt 32 the plunger 34 is transmitted. Another force F2 acts on the bolt 46, which force F2 on the pressure column 31 and the bolt 33 transferred to the plunger 34 becomes.

In ideal conditions, the sum of all works forces generated by the individual tools, i.e. the Total force at the location of the center line 47, i.e. Point C. the plunger 34. Since the lever arm length C → 32 is equal to that Lever arm length C → 33, the relationship obviously applies F1 = F2 and thus the ram 34 remains parallel to the clamping table 39 aligned.

It is now assumed that from the beginning reasons mentioned an eccentric force F3 at the Place E acts on the plunger 34. Change with it the lever arm lengths, whereby in the drawn example the lever arm length E → 32 is greater than the lever arm length E → 33 is. The plunger 34 thus begins opposite the clamping table 39 to be skewed, with the point E the Center of rotation is, as drawn in FIG. 2. there is the plunger 34 in the desired, parallel to Clamping table 39 extending position with an extended Line drawn. The leaning ram 34 with the guide columns 35, which also run obliquely, 36 is drawn in dashed lines.

Aside from increased friction in the various Storage, e.g. the column guides 37, 38 are also the individual tool parts, e.g. punch skewed relative to the tape to be machined, which becomes a leads to inaccurate punching results and in the case for example a die located on the lower tool, which cooperates with the cutting stamp and obviously remains vertically aligned, it becomes obvious that there will be increased wear and tear.

In the state of equilibrium of the plunger 34 applies the relationship F1 x (C → 32) = F2 x (C → 33). However, since the Forces F1, F2 only when force F3 acts, that is occur while the work is actually being done the plunger 34 must be inclined in the unloaded state take the opposite of that in Fig. 2nd shown inclination, i.e. so the place 32 higher than the location 33 is relative to the clamping table 39. This inclination is shown in FIG. 3.

It can be seen that the location of the pivot pin 17 by adjusting the threaded spindle 23 has been moved down. The one-armed lever 15 has thus been pivoted so that the location of the bolt 46 is shifted downward by the distance K and accordingly the inclination arises. The plunger 34 is in the controlled misalignment with an extended Line shown. Its parallel position to the correct one Machining the workpiece when the eccentric occurs Force is drawn in dashed lines.

This position can now be described by the Ram height adjustment units (in other versions the height adjustment devices 55, 56 of the clamping table) and a convenient sampling of values, or influence the controls 28, 29.

For this purpose, various designs of the invention are Procedure possible.

According to one version, at least one place, preferably two opposite each other arranged places, one or more strain gauges 48, 49 connected to the press frame 1. This Strain gauges 48, 49 are on both sides of the press frame 1 arranged. The output signals of the strain gauges 48, 49 are supplied to the controls 28, 29. When an off-center load occurs F3 of the plunger 34 causes a transmission of the corresponding Force an expansion of the press frame 1 by the Strain gauges 48, 49 is perceived. The corresponding Signal, or the corresponding signals are from the strain gauges 48, 49 fed to the controls 28, 29, which via the frequency-controlled motors 26, 27 cause the spindles 22, 23 to rotate until the tappet 34 approximately when the eccentric force F3 occurs is aligned parallel to the clamping table 39, or in unloaded, removed from the mounting table 39 the described, opposite oblique position. The controls 28, 29 are obviously programmed in such a way that the ram height during machining the workpiece is retained. The controls 28, 29 can obviously communicate with each other in terms of signals stand so that a comparison of the two Strain gauges 48, 49 originating signals takes place and the spindles 22, 23 are adjusted accordingly, so that the plunger 34 is in an oblique position in the unloaded state occupies, almost parallel in the loaded state is held to the chuck table 39, and also the preset Ram height is maintained.

According to another variant are alternate N-S polarized rods 50, 51 with, for example connected to the plunger 34. These rods 50, 51 act with fixed detectors 52, 53 together. By means of this Rods 50, 51 and detectors 52, 53 can be one Determine the misalignment of the ram 34 directly, and then appropriate signals from the controls 28, 29 are again supplied become. Obviously, parallelism can also of the plunger 34 determined relative to the clamping table 39 are so that the position of the plunger 34 is maintained unchanged and the ram height position.

Which of these two variants is chosen depends on various factors, such as construction the punch press, size of the load, properties of the workpiece, precision to be achieved Product, as shifts due to games in e.g. Do not store the punch press using strain gauges, and only polarized by means of the arrangement with the N-S Rods can be perceived.

Another variant is based on calculations. When procuring a new punch press, the Buyers calculate the punching force for the work to be carried out Work is necessary and accordingly the machine size determine. (These calculations can e.g. can also be carried out by the tool manufacturer). The punching force depends, among other things, on the ones to be made Work off, e.g. Stamping, embossing, bending etc., from the Quality of the material of the strip to be processed, on the thickness of the same, etc. The Calculations for each tool part (cutting stamp, embossing stamp, etc.) can be carried out individually. So that is the force effect for each tool part is known exactly. The exact location of this tool part is also known with the upper tool or with the lower tool of the subsequent cutting tool is connected.

This makes it particularly easy to when a new metal strip to be machined in the punch press is inserted for each working stroke, i.e. each Processing step exactly the size of the off-center Force F3 and its location (e.g. distance between location 33 and position E). You can also calculate the forces F1 and F2, and from these values can be also the necessary misalignment of the plunger 34 in the unloaded Calculate condition.

These values can now be entered into the controls 28, 29, so that especially when Punching the plunger while doing the work on the metal belt fully automatically parallel to the clamping table remains.

4 is the gradual adjustment of the plunger 34 explained when punching. It must be noticed that it is a follow-up cutting tool deals, which a large number of individual tools (e.g. Stamp) has in the longitudinal direction of the follow-up cutting tool are arranged sequentially. The more Individual tools on the gradually advanced band-shaped Impact the workpiece, the bigger it becomes force acting on the plunger 34, however, depends the magnitude of the purely eccentric force from the place of its Action, i.e. the lever arm lengths mentioned above. It is further assumed that if all individual tools hit the band-shaped workpiece, i.e. during the ongoing machining process, not off-center Force is present, i.e. the tools accordingly are distributed.

If a new band-shaped workpiece is inserted into the punch press during the punching process, the foremost individual tool of the sequential cutting tool strikes the same next to the front edge of the band-shaped workpiece during the first working stroke. A relatively small eccentric force acts on the plunger 34, the lever arm length described above corresponding to the distance 32 → K. To maintain the discussed parallelism between ram 34 and clamping table 39, the bolt 46, see FIG. 3, is lowered by the distance K ₁ .

During the next working stroke, the force of the first individual tool and the force of a second tool following it in the longitudinal direction of the follow-up cutting tool or the feed direction of the band-shaped workpiece act on the plunger 34, so that a larger eccentric force acting on the plunger 34 but with a smaller one Lever arm length is created. Accordingly, the ram is skewed by the distance K ₂ .

For the next working stroke, the misalignment is K ₃ , and thereafter the misalignment is K ₄ , which misalignment is assumed to be equal to the value K of FIG. 3 in the illustrated embodiment.

The greatest misalignment is reached at K ₅ , ie here the product lever arm length x eccentric force F _{3 has} the greatest value. In this position, the front edge of the band-shaped workpiece which is gradually advanced is located at the center line 47.

During the subsequent working stroke, the force of a first individual tool arranged on the other side of the center line 47 acts on the plunger 34, so that the overall eccentric force is reduced and the inclined position of the plunger 34 only has to have the amount K ₆ . In the subsequent working strokes, during which the forces of further individual tools arranged on the other side of the center line 47 gradually act on the ram 34, the misalignment from working stroke to working stroke is reduced, as with the amounts K ₇ and K _{8 of} the inclined position of the Plunger 34 is specified.

Finally, the forces of all individual tools of the follow-up cutting tool act on the ram, so that (ideally) no ram position of the ram 34 is necessary, as indicated by K ₉ .

If, however, for any manufacturing reasons, the follow-up cutting tool would have to be designed in such a way that an eccentric force acts continuously on the ram 34 or clamping table 39, the ram 34 must be continuously inclined, for example in accordance with K ₈ .

During the continuous operation of the punch press must the mutual angular position between the plunger 34 and the clamping table 39 are not recorded on each working stroke become. The angular position can also be in the sense of a regular checks are only recorded periodically.

Claims (16)

Method for controlling the mutual angular position between a ram (34) and a clamping table (39) of a punch press, which ram (34) with an upper tool part (57) and which clamping table (39) with a lower tool part (58) of a sequential cutting tool for processing a step-by-step process connected by the punch press band-shaped workpiece, in which processing during the action of the secondary cutting tool on the workpiece and consequent action of a force on the ram (34) and on the clamping table (39) an at least approximately parallelism between the ram (34) and the Clamping table (39) must be present, characterized in that, for an operating state with a force eccentrically acting on the plunger (34) and on the clamping table (39), the plunger (34) and / or the clamping table (39) during one of these forces not exposed operating state in an inclined position to reach egg ner such mutual angular position is controlled, or that the at least approximated parallelism is achieved during the action of the eccentric force. A method according to claim 1, characterized in that the size and the location of the off-center force is calculated before the punch press is operated and the resulting inclination of the ram (34) and / or clamping table (39) is calculated and in one controlling the respective inclination Control apparatus (28, 29) is stored so that the required inclination of the ram (34) and / or clamping table (39) can be generated by the control apparatus (28, 29) during the operation of the punch press. A method according to claim 1, characterized in that the mutual angular position between the plunger (34) and the clamping table (39) is measured by measurement during the action of the eccentric force and, when determining a deviation from the at least approximated parallelism, the required inclination for submitting the at least Approximate parallelism is generated during an operating state of the punch press not exposed to this eccentric force. A method according to claim 3, characterized in that the mutual angular position is detected periodically. A method according to claim 3, characterized in that the mutual angular position is detected each time the eccentric force acts. A method according to claim 3, characterized in that the mutual angular position is determined by deformation measurements at at least two points on the punch press, at which the strains are different in an operating state with an eccentrically acting force. A method according to claim 6, characterized in that the deformation measurements are carried out by means of strain gauges (48, 49) connected to the press frame (1). Method according to Claim 7, characterized in that the measured values determined by the strain gauges (48, 49) are compared with one another and, if the measured values deviate from one another, the mutual angular position in the unloaded operating state of the punch press is determined as a function of the extent of the deviation. A method according to claim 3, characterized in that the mutual angular position is determined by measuring the distance between the ram (34) and the clamping table (39) at at least two points. Method according to Claim 9, characterized in that the measured values determined by the distance measurements are compared with one another and, if the measured values differ from one another, the mutual angular position in the unloaded operating state of the punch press is determined as a function of the extent of the deviation. A method according to claim 1, characterized in that the size and location of the off-center force and the resulting mutual angular position of the ram (34) and / or clamping table (39) prior to the operation of the punch press for each individual working stroke of the ram (34 ) are calculated and stored in a control apparatus controlling the respective inclination, so that the required inclination of the ram (34) and / or the clamping table (39) can be generated by the control apparatus (28, 29) during each working stroke during the operation of the punch press , A method according to claim 1, characterized in that the size and location of each force acting on the ram (34) and on the clamping table (39) during the operation of the punch press and the resulting mutual angular position of the ram (34) and the clamping table ( 39) for all individual successive working strokes and related to a respective sequential cutting tool before the punch press is operated and the calculated values are stored in a mutual angular position between the ram (34) and the clamping table (39) controlling the control apparatus, so that during the entire operation the punch press, including every punching process, the at least approximated parallelism is ensured. A method according to claim 1, characterized in that in order to achieve this at least approximately parallelism in the event of a force acting off-center on the ram (34) and on the clamping table (39), the first distance (C -32) and from adjacent second end regions of the ram (34) and the clamping table (39) has a second distance (C-33), which second distance (C-33) is smaller than the first distance (C-32), an inclined position of the ram (34) and / or the clamping table (39) is initiated during an operating state not exposed to this force, according to which the distance (C-32) between the first end regions of the ram (34) and the clamping table (39) is greater than that Distance (C-33) between the second end regions of the ram (34) and the clamping table (39) is that the at least approximately parallelism is achieved when the eccentric force occurs. Punching press for carrying out the method according to claim 1, which punching press has a press frame (1), a ram (34) guided in the press frame (1) and a clamping table (39) mounted in the press frame (1), which ram (34) for connection to an upper tool part (57) and which clamping table (39) are designed for connection to a lower tool part (58) of a sequential cutting tool, which is intended for machining a strip-shaped workpiece which is gradually advanced through the punching machine, which punch press is a device (18, 20, 22 , 24, 26, 28; 19, 21, 23, 25, 27, 29) for adjusting the height position of the ram (34) and / or a device (55, 56) for adjusting the position of the clamping table (39), characterized in that that the device for adjusting the height of the plunger has a plurality of height adjustment units (18, 20, 22, 24, 26, 28 and 19, 21, 23, 25, 27, 29) and / or the device for position adjustment d it has a plurality of position adjustment units (55 and 56), that each height adjustment unit and each position adjustment unit has its own actuating gear (20, 28 and 27, 29), and that the punch press has a control device by means of which the actuating gear (20, 28 and 21, 29) can be operated independently of one another. Punching press according to Claim 14, characterized by at least two strain gauge devices with strain gauges (48, 49) which are connected to the press frame and are connected to the control apparatus and which are connected to the press frame (1) at such locations that are off-center at one point the plunger (34) and the force acting on the clamping table (39) are subjected to different expansions. Punching press according to Claim 14, characterized by at least two distance measuring devices (50, 52 and 51, 53) which determine the respective distance between the ram (34) and the clamping table (39) and are connected to the control apparatus and which are arranged at such points at a distance from one another are in which there are different distances between the plunger (34) and the clamping table (39) in the case of a force acting off-center on the plunger (34) and on the clamping table (39).

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