EP0741001B1 - Stamping, printing and punching machine - Google Patents

Description

The invention relates to an embossing printing and punching machine according to the preamble of independent claim. From EP 596 697 is a hydraulic Sheet metal press with automatic hydraulic pressure control for the deformation of Body panels known. Here the press pressure is controlled by four hydraulic cylinders in the four corners of the press, the pressure values using four sensors can be controlled automatically independently of each other. Such slow hydraulic presses with relatively rough hydraulic pressure control However, the requirements of faster, more precise embossing presses can absolutely not meet.

On the other hand, embossing presses with precise mechanical presses are known, which, however, do not have an automatic pressure force control. With such Embossing presses are usually only at one point of the pressure force measurements Machine and outside of the embossing printing area known. On the one hand, this requires elaborate conversions depending on the location of the clichés to estimate the Compressive forces on the embossed image surface. Furthermore, these force measurements are inaccurate and unreliable. Influences that change the working pressure and thus the Print quality deteriorate, and therefore cannot be recorded well Changes in the course of a work process can be compensated even less. Uneven pressure distributions on the embossed printing area cannot be recorded become.

It is therefore an object of the present invention to emboss and print Punching machine to create an accurate recording of the pressure forces and thus also the setting of an optimal embossing quality enables and which above all the negative influences and changes during operation automatically if possible can largely compensate so that constant highest quality is achieved.

This object is achieved by an embossing-printing and Punching machine according to claim 1. The arrangement of several pressure sensors around Embossed printing area around enables precise pressure force determination and Monitoring. The combination of mechanical precision press with the mechanical positioning device with controlled sliding drive with which Pressure control program and with pressure force control through mechanical displacement the positioning device in very small steps in the Y direction enables set optimal working pressures and these also under negative influences of the operation to be kept constant and optimal, so that constant highest embossing quality is achieved.

The dependent claims relate to advantageous developments of the invention, which further automate, improve and simplify their functions make more reliable. The automatic execution of Operations such as touching, keeping working pressure constant and almost any to be able to drive programmable pressure setpoint curves. The inventive The machine enables compliance with safety and limit values as well as Detection of uneven, eccentric pressure distribution on the Embossing surface. Above all, however, the various variable influences on the Working pressure which deteriorate the quality e.g. due to thermal influences or increasing, permanent deformation or change in thickness of the dressing and due to fluctuations in paper thickness, largely compensated. So that is highest possible and constant embossing quality with minimal operating effort and accessible with the greatest possible security.

Fig. 1a

eine erfindungsgemässe Maschine

Fig. 1b, 2

Anordnungen von Druckkraft-Sensoren und exzentrische Belastungen

Fig. 3

ein Schaltschema der Maschine

Fig. 4

Druckkraft-Verschiebungs-Charakteristiken X(Y)

Fig. 5

Beispiele verschiedener Druckkraftwerte

Fig. 6

verschiedene Einflüsse auf die Druckkraft-Verschiebungs-Charakteristiken

Fig. 7

Beispiele zeitlicher Druckkraftverläufe X(t)

Fig. 8

programmierbare Sollwertverläufe der Druckkraft XX(t)

In the following, the invention is further explained with the aid of examples and figures. Show it:

Fig. 1a

a machine according to the invention

1b, 2

Arrangements of pressure force sensors and eccentric loads

Fig. 3

a circuit diagram of the machine

Fig. 4

Push Force Displacement Characteristics X (Y)

Fig. 5

Examples of different compressive force values

Fig. 6

different influences on the pressure force displacement characteristics

Fig. 7

Examples of temporal pressure force curves X (t)

Fig. 8

Programmable setpoint curves for the pressure force XX (t)

1 a shows a side view of an embossing printing and punching machine 1 according to the invention with an upper press part 3 which is held by side supports 6, with an upper support 5, a positioning or displacement device 10 and a press head 9. This head 9 carries a tool - Or Clichéplatte 4 with a heater 7, which includes, for example, several individually adjustable heating zones.
A lower press part 19 here has a toggle lever mechanism with four toggle lever pairs 17, which move a press table 13 up and down by a stroke H of, for example, 80 mm. A counterpressure or dressing plate 14 is attached to the table 13, the surface of which forms the embossing printing surface F (ie the maximum usable embossing surface). Clichés 8 are attached to the tool plate 4, the surfaces of which define the embossed image area FC (see FIGS. 1b and 2). A dressing 15 adapted to the clichés 8 is inserted on the dressing plate 14, which consists, for example, of a 1-2 mm thick, fabric-reinforced plastic plate, of hard laminate, for example Pertinax, or of less hard material such as pressboard or unreinforced plastic. The material and layer thickness are adapted to the clichés and the embossed goods. By locally placing thin layers of paper, for example 20 µm thick, the preparation is adjusted in a known manner to optimal embossing quality.

The optimal embossing pressure or the embossing pressure force X is determined by displacement of the positioning device 10 in the Y direction. As a drive 20 is a controlled adjustment motor, e.g. a servo motor with incremental encoder and an assigned motor control 21. The shift Y takes place via a transmission 16 to a spindle 12, which has a sliding wedge 11 moves. The maximum possible displacement range of Y is e.g. 4 mm, which enables different layer thicknesses of dressing and compensate for embossed goods.

As shown in Figure 1b as a partial representation of the machine 1 seen from above is, several compressive force sensors S1 to S4 or S5 to S8 around the Center Z of the embossing printing surface F of the plate 14 is arranged around. The Compression force measurement takes place e.g. through strain gauges such as strain gauges (DMS) or piezo elements, which are on suitable, under load the chassis elements of the machine that experience significant stretching are attached are. As an example here are strain gauges S1 to S4 on the side beams 6 attached. These could also be attached to the press head 9. However, the pressure forces can also be measured with pressure cells S5 to S8 which e.g. arranged in the four corners under a toggle 17 are as shown in Fig. 1a. Through this rectangular arrangement the force measuring sensors S1 to S4 or S5 to S8 around the center Z of the embossing pressure surface F around it is possible to put eccentric loads through the embossed image area FC, i.e. due to the location of the Clichés 8, easy to grasp and to monitor.

FIG. 2 shows a further example with a triangular arrangement sensors S9 to S11 and an eccentric arrangement of the clichés or of the embossed image areas FC1 and FC2, which put a higher load on the Side of sensor S9. By detecting and monitoring uneven Above all, loads can damage the press be avoided. So each individual sensor can be considered the maximum allowable Value assigned a safety value XMi and its compliance monitored become. From the measured values of sensors S1 to S4, i.e. from the partial pressure forces XSi, (e.g. according to Fig. 1a) becomes the total compressive force by superposition X determines: X = XS1 + XS2 + XS3 + XS4. As the maximum allowable Values for a given machine are e.g. a safety value XM = 1500 kN fixed, and a safety value XMi = for each individual sensor 450 kN. All safety values XM and XMi must always be observed during operation become.

Figure 3 shows a circuit diagram of the machine according to the invention with pressure transducers S1 to S4, which with the pressure control 30 or the machine control 2 are connected. The positioning servomotor 20 with motor control 21 is also with the machine control 2 and the pressure control 30 connected. To the operating and display device 40, which e.g. as Is designed touch screen, there is a bidirectional communication with the controls 30 and 2. A further output 35 can additionally be provided be for bidirectional connection to an external computer, e.g. with a PC, to output operating data and to enter additional data Functions.

FIG. 4 shows a characteristic that is valid for a specific dressing X1 (Y), i.e. that in function of the displacement Y by the press on the embossing generated compressive force X1. This characteristic can be driven automatically and be included if e.g. in the control program following function is entered:

Increase displacement Y linearly as a function of time until the pressure force value X1 has reached a given value Xmax.

This characteristic X (Y) is of course dependent on the clichés and the finish (type of material, thickness and size), ie it characterizes this finish and this specific embossing process. During operation, this characteristic X (Y) of a given dressing changes gradually, for example from curve X1 (Y) in the initial state to curve X2 (Y) after a certain runtime, because the dressing wears out or is compressed more and more over the course of time an embossing. This must be compensated for by a correspondingly larger displacement Y in order to achieve the same pressure force value X, for example the working value XA: from YA1 to YA2 with YA2 = YA1 + Y12
The head 9 must therefore be readjusted around the area Y12.

Other influences that change or shift the Characteristics X (Y) effect are discussed with reference to FIG. 6.

FIG. 5 shows the course of pressure measurement signals as a function of time t: X1 (t). Over a machine cycle of 360 °, in which the toggle press executes a stroke H, the press is only under pressure for approx. 20 ° - 25 ° (On-press area). Throughout the rest of the time from 335 ° -340 ° the press exerts no pressure (X = 0, area Ab-Druck, off-press). The pressure curve has a broad maximum at top dead center OT. The displacement in Y by the adjusting device 10 always takes place without Pressure (i.e. in the area of impression). During this time, too Zero points of the sensor values adjusted (adjustment of a zero point drift of the Measurement signals, e.g. due to thermal influences on the sensors). With everyone Press stroke is the effective pressure force X as the difference of the Measured values between top dead center OT and the pressure area determined. Also for this adjustment the zero point drift of the sensor measurement signals a certain tolerance range can be provided and monitored: System limit values of the zero point, if exceeded, error messages respectively.

The pressure force curves X1, X2, X3, X4 (t) shown as examples - accordingly different displacement values Y1, Y2, Y3, Y4 - illustrate different ones Embossing cycles.

Here X1 corresponds to the work value XA, at which the optimal embossing quality is achieved. An adjustable and selectable tolerance + XT, -XT is assigned to this work value XA.
The curve with compressive force value X2 is below the tolerance range XA - XT,
the value X3 lies above the tolerance range XA + XT
and the curve with pressure force value X4 corresponds to the safety value XM, ie the maximum permissible press pressure.

The tolerance value XT is e.g. adjustable between 10 - 100 kN. This tolerance range is only used, however, if not in the operating mode - "REG" = automatically keep work value constant - driving; because there will be XT with a much smaller one within this tolerance range Control difference DX controlled (see Fig. 7).

FIG. 6 illustrates various influences which change over time Characteristic Y (X) (FIG. 4), or changes in threshold values Y0 (t) and work values YA (t) for given constant compressive force values X0 and XA effect: This is shown with the curves Ytemp, Yzu and Ypap.

Different thermal expansions occur when the machine is heated up on what corresponding changes in the distance between tool plate 4 and finishing plate 14 result. This shows the Ytemp curve.

Continuously progressive wear and permanent compression the finish 15 causes e.g. a course according to curve Yzu. If the If the dressing is changed (the Y value is adjusted), a results shifted curve Yzu2.

There is a further influence on the shift values Y0 and YA (t) Variations in paper thickness, as illustrated by the Ypap curve. The super position all of these influences Ytemp, Yzu, Ypap etc. ultimately result in resulting overall change in the characteristic X (Y) over time. This matches with e.g. curve X6 (t) in FIG. 7.

With the machine according to the invention, the most varied of operating modes are possible possible. These are stored as functions in the print control program 30 and can be selected via the control and display device 40, or also can be entered externally via output 35. So that can various operating parameters regarding an embossing print job as well Limit values, tolerances, switching values and programmed setpoint curves (see Fig. 8) entered or reprogrammed.

A practical example is the automatic execution of an operating mode or function "TOUCH" = touch: The press is in the brought top dead center and stopped. The pressure measurement takes place here continuously and no longer cyclically as during normal operation the machine in "RUN" mode (see Fig. 5). In this situation OT is now the adjusting device 10 is automatically shifted, i.e. Y is increased until a Pressure rise is measured. If a minimum adjustable pressure threshold X0 is reached, the shift Y is stopped and the corresponding one Value Y0, i.e. this position, saved. This is in Fig. 4 shown. The pressure threshold is e.g. X0 = 5 - 10 kN, i.e. around 1% of Labor value XA.

A particularly important function "REG" is the labor value XA, i.e. the optimal pressure for the highest quality of a given print job automatically and exactly to keep constant. This is done by variation the pressure force X first determines the work value, which is an optimal one Embossed image results. This value is defined as labor value X = XA and fixed. Then the function "REG" is selected, with which this labor value XA is automatically constant in the following, i.e. within a narrow control gap DX is held.

This process takes place e.g. according to the following scheme "REG":

Wenn die Abweichung Xm - XA grösser ist als die Regeldifferenz DX, dann erfolgt eine Nachstellung von Y um einen Nachstellschritt DY.

Zusätzlich wird geprüft, ob der Nachstellbereich YN überschritten ist, worauf allfällig ein Signal ausgegeben und die Maschine gestoppt wird.

Anschliessend erfolgt eine neue Mittelwertbildung Xm.

When the pressure measurement is set to "RUN" operation
and the "REG" key is pressed
and the Y adjustment is released,
then the setpoint Xset = XA is compared with the actual value = mean Xm:

If the deviation Xm - XA is greater than the control difference DX, Y is adjusted by an adjustment step DY.

In addition, it is checked whether the adjustment range YN is exceeded, whereupon a signal is output and the machine is stopped.

This is followed by a new averaging Xm.

In order to avoid unnecessary constant back and forth regulation, the actual value of the regulation is preferably determined continuously as the mean value Xm from the n-last pressure force measurements. For example, n = 5, which is the mean
Xm = 1/5 of the sum of the last five measured values X.

The control difference DX is e.g. 5 - 10 kN and the regulation adjustment step DY e.g. 1 - 2 u.

A readjustment area YN selected and entered by e.g. YN = 0.1 mm. Once the automatic Tracking Y reaches this value (e.g. YA1 + YN in Fig. 4), a signal is output and the machine is stopped if necessary. Then can the operator decides whether he goes beyond this adjustment range YN should continue - by specifying a new second adjustment range from e.g. 0.05 to 0.1 mm - or whether the dressing changed and restarted shall be.

Another important safety function is the "automatic Drive from pressure "is reached. The sheet entry into the press supervised. If no incoming sheet is found, the displacement device 10 immediately towards -Y, e.g. 1 mm, retracted (according to arrow R in Fig. 4) before the next stroke of the toggle press takes place. This prevents the dressing 15 from being embossed if none Bow runs in.

The advantages of this automatic regulation of the labor value are shown in Fig. 7 further illustrates which different temporal pressure force profiles X (t) shows. As explained above, the curve X5 (t) runs according to the "REG" mode in a narrow control range between an upper limit XA + DX and a lower limit XA - DX. Here is regulated to constant pressure.

In contrast, curve X6 (t) shows the pressure force curve if the displacement Y is kept constant. The influences explained in relation to FIG. 6, or changes in Y due to temperature, preparation and paper thickness, result in a corresponding, significant change in the resulting pressure force X6 (t) with a constant displacement Y. Until now, these influences had to be continuously monitored and monitored by the machine operator periodically be compensated by hand by tracking the displacement Y, which corresponds to the curve X7 (t). This was very complex and moreover inaccurate, so that practically only an effectively driven curve X7 (t) with significantly fluctuating pressure force values was achieved.
The resulting embossed print quality is of course much better in accordance with the new curve X5 (t) with automatic constant control than in the curve X7 (t) that was previously achievable. In addition, operating errors can also be avoided with the automatic functions and controls of the machine according to the invention.

However, the pressure force curve X (t) driven can not only be automatic are kept constant according to curve "REG", but in principle it can also according to any given setpoint curve for the pressure force XX (t) be regulated by corresponding adjustment of the shift Y. To Figure 8 illustrates two examples. The curve XX1 shows a rapid Increase followed by a slow decrease and finally ending in constant pressure force according to. Operating mode "REG". According to curve XX2 the Compressive force gradually increased, e.g. from X = 600 kN each by 20 kN to 700 kN is reached. With this e.g. for each level 20 identical proofs with the Machine are generated automatically. This can result in the best print quality optically determined and the corresponding pressure value selected as work value XA become.

Through suitable setpoint specifications XX (t) or through controlled shift functions Y (t) can e.g. optimal parameters for the characterization of Stamping orders can be determined automatically, more precisely and more comprehensively.

Claims (13)

1. Stamping, printing and punching machine with a machine control (2), a press top (3) with a controlled adjusting device, as well as with a press bottom (19) with several pressure sensors (S1 to S4) for measuring compressive forces X which are arranged around the center Z of the blocking surface F, with a pressure control program with functions for pressure force control and with an associated control and display unit (40), characterized by a press top with a heating (7), a block plate (4) for fastening dies (8)

   and a mechanical positioning device (10) which comprises a mechanical displacement drive (20) with associated motor control (21) for vertical displacement of the block plate in Y-direction,

   by a press bottom with a mechanical toggle press (17) with a precisely defined press stroke (H)

   and a back pressure plate (14) and a make-ready (15) as support for sheets to be embossed,

   whereby the pressure control program (30) comprises predeterminable pressure difference values (DX) and/or readjustment steps (DY) for adjustment of the compressive force value X and whereby the pessure force control is carried out by means of mechanical displacement of the positioning device (10) in Y-direction.
2. Machine according to claim 1, characterized in that on the machine are provided four pressure sensors (S1 to S4), each associated with one corner of the blocking surface F.
3. Machine according to claim 1, characterized in that as pressure sensors strain gauges (DMS) are fitted to bearing parts (6) of the press top (3).
4. Machine according to claim 1, characterized in that the positioning device has a displacement wedge (11) and a controlled adjusting motor or servomotor (20).
5. Machine according to claim 1, characterized in that the pressure control program (30) has several operating modes (REG, TOUCH) selectable on the control means (40).
6. Machine according to claim 1, characterized in that the pressure control program (30) has a TOUCH function.
7. Machine according to claim 1, characterized in that the pressure control program (30) has a "keep operating value constant" function (REG).
8. Machine according to claim 1, characterized in that the pressure control program (30) has a "pressure desired value distributions (XX1, XX2) control" function.
9. Machine according to claim 1, characterized in that the pressure control program contains fixed or predeterminable saftey values (XM, XMi), tolerance values and/or limiting ranges (XT).
10. Machine according to claim 1, characterized in that the pressure control program contains predeterminable switching values (XT, DY), at which secondary functions such as machine stop or warning signals are triggered.
11. Machine according to claim 1, characterized in that the pressure control has a three-point control, with a control difference DX and a displacement readjustment step DY, the actual value being constantly formed as a mean value Xm from the last n pressure measurements.
12. Machine according to claim 1, characterized in that a selectable readjustment range YN can be set and when reached initiates a signal.
13. Machine according to claim 1, characterized in that the pressure control has a bidirectional output (35) for an external computer.

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