Bottom dead centre correction device for servo press machines

Description

[0001] The present invention relates to a bottom dead center correction device for a servo press machine, in which a slide is raised and lowered with a servo motor as the power source. The present invention is effective for correcting the bottom dead center in one micron units for each stroke of the slide using a detector sensor provided on a die of the machine for detecting bottom dead center measurement value.

[0002] It also provides bottom dead center correction in response to fluctuations in the moulding load due to deformations resulting from unevenness in the hardness of the material to be processed.

[0003] A servo press machine drives the servo motor so that the bottom dead center of a stroke of the vertical motion of the slide has, as the bottom dead center command value, a bottom dead center setting value which has been set at a control device. The bottom dead center of the slide stroke is maintained at a constant. A bottom dead center detection value is detected by a position detection device, which detects the position of the slide. In addition, by having feedback of the bottom dead center detection value, there is a correction per stroke. Fluctuations in the bottom dead center resulting from distortions of frame parts due to pressure from moulding and deformations due to heat generated during rotation and sliding are corrected.

[0004] In the prior art, for example, Japanese Laid-Open Patent Number 6-218594 corrects the distortion amount of the frame.

[0005] In the above described technology of the prior art, a test moulding is conducted when setting the bottom dead center, and the setting value for the bottom dead center is determined from the precision of the moulded product. In later mouldings, the fluctuation of the bottom dead center due to distortion of frame parts and deformation due to heat generation of moving parts is detected by a slide position detection device. Because correction is conducted to match the detected value with the setting value, the precision of the bottom dead center can be made to 5-10 microns.

[0006] However, the slide position detection detects the position of the slide, but does not measure the actual bottom dead center of the die. If there is any fluctuation in the actual bottom dead center of the die due to a load and the like during the moulding, there is no method for correction. There is no way of having a correction that can achieve a bottom dead center precision greater than that described above.

[0007] In the known device, the fluctuations of the bottom dead center due to deformations of the construction members as a result of moulding load and as a result of heat are corrected, and the distance between the upper surface of the bed or bolster and the lower surface of the slide is measured directly with a linear scale, and the height fluctuation amount is continuously being corrected.

[0008] In another prior device, corrections not only of the fluctuations of the bottom dead centre due to deformation of the construction parts of the servo press but also fluctuations due to deformation of the die are made. For example, the touch point at which the punch of the upper mould contacts the processing material, which is supplied onto the lower mould, is detected. At the time of detection, the distance from the bed or bolster upper surface to the slide lower surface is measured. The fluctuation amount of the distance is continually being corrected. According to this device, there can be corrections in response to changes in the thickness of the processing material.

[0009] In the above described prior art, with the former method, in which there is correction for the fluctuations of the bottom dead centre due to deformations of the construction parts of the servo press or the die resulting from moulding force or heat, the bottom dead centre precision is maintained at 5-10 microns.

[0010] JP 2002/280100 describes a bottom dead centre correcting device of a servo press machine for correcting the bottom dead centre point with a high precision. A bottom dead centre detection sensor and a temperature sensor are installed on a lower mould of a two-part upper and lower mould of the press machine. The bottom dead centre point of the slide motion which is set by a numerical controller is corrected in response to a measured bottom dead centre position of the detection sensor and the measured temperature drift of the bottom dead centre detection sensor due to the rise in temperature of the mould which is detected by the temperature sensor during moulding.

[0011] Furthermore, with the latter method, in which in addition to the former method, there is correction for fluctuations of the bottom dead centre due to changes in the thickness of the processing material, the bottom dead centre precision can be improved by the few microns.

[0012] However, there still remains the problem of correcting fluctuations of the bottom dead centre arising from fluctuations in the moulding load due to variability in the hardness of the processing material. In general, a coil material is used for the processing material. However, even if the coil material is manufactured under conditions in which the thickness and hardness are adequately maintained, the beginning, middle, and end of the coil may not be consistent. The following improvements are still needed: preventing fluctuations in the moulding amount resulting from fluctuations in hardness; improving the bottom dead centre precision from the 5-10 microns of the prior art; and improving the product precision.

[0013] According to the invention there is provided a servo press machine as claimed in Claim 1.

[0014] According to the invention, a device for correcting a bottom dead centre by detecting a moulding load in a servo press is provided. The servo press has a servo motor with numerical control as a drive source and provides a slide with a raising and lowering motion. With this aspect, there is provided: a scale detection device, which detects the distance between a bed or bolster upper surface and a slide lower surface (henceforth referred to as 'slide position') and which outputs an electrical position signal; a current detection device, which detects a current value which is supplied to the servo motor and corresponds to the load value of the slide; and an NC control device, which controls a rise and fall motion of the slide by controlling the current value that is supplied to the servo motor so that it corresponds to a pre-set motion.

[0015] In addition, when the slide load value, which is calculated from a current value inputted from the current detection device reaches a set value, the NC control device corrects the set bottom dead center of the slide according to the difference between the other value and its set value.

[0016] In this bottom dead center correction device, when the slide load value, which is calculated by the NC control device, reaches a pre-set value, if the slide position, which is outputted from the scale detection device, is higher than a pre-set position, the processing material is determined to have a high hardness, and the set bottom dead center of the slide is corrected downward by the amount of the correction value, and the slide is lowered. Conversely, if the position is lower than the pre-set position, the processing material is determined to have a low hardness and the set bottom dead center of the slide is corrected upward by the amount of the correction value, and the slide is lowered.

[0017] Furthermore, a touch point, which is where an upper mould which is lowered together with the slide contacts a processing material supplied onto a lower mould, is detected by a rise in the current value outputted from the current detection device. When the touch point is detected, the corrected value for the set bottom dead center of the slide obtained from an output of the scale detection device can be corrected. In other words, the set bottom dead center of the slide can be corrected in response to changes in the thickness of the processing material.

[0018] Various embodiments of the invention will now be more particularly described, by way of example, with reference to the accompanying drawings, in which:

Fig. 1 is a schematic depiction of a first arrangement of bottom dead center correction device of a servo press machine in which the bottom dead center position of the slide is corrected by a bottom dead center measurement detection from a sensor on a die.

Fig. 2 is a block diagram associated with the detection device of Fig. 1.

Fig. 3 is a schematic diagram of a second arrangement of correction device employing a detection of a load on the servo press.

Fig. 4 is a block diagram associated with the detection device of Fig. 3.

Fig. 5 is a front view partly in section, showing the construction of the servo press machine.

Fig. 6 illustrates curves representing the slide motion before and after correction.

[0019] Referring to the Fig. 1 arrangement, a servo press machine 1 slide 3 is provided on a frame 2 of servo press machine 1 in a vertically free up and down movement manner. A male screw member 4 is supported in a freely rotating manner on the top part of frame 2 in a vertical reaction. A female screw part 3A of slide 3 and the lower end of male screw member 4 are engaged. Screw member 4 is connected to servo motor 5.

[0020] Servo motor 5 conducts the necessary rotation by a controlled current which is supplied from an NC control device 6 via a power current circuit 7. Servo motor 5 makes slide 3 move vertically in a straight line at a constant stroke via male screw member 4.

[0021] A current detection device 8 is provided on power current circuit 7. The supplied current value is detected. The detected current value is inputted into NC control device 6 and is used to calculate the pressure of slide 3. Furthermore, in order to detect the position of slide 3 in its vertical movements, a slide position detection device 9, which uses a linear scale, is provided on a part of frame 2 close to or adjacent slide 3. Scale detection device 9 can detect slide position in 1 micron units.

[0022] On the lower part of frame 2, in other words on die 10 which is attached between the bed part and slide 3, a bottom dead center detection sensor 11 and a temperature sensor 12 are provided on lower mold 10B.

[0023] Bottom dead center detection sensor 11 detects the over current generated when upper mold 10A approaches lower mold 10B, and it measures the distance between upper mold 10A and lower mold 10B. The measurement precision is 0.1 microns.

[0024] The bottom dead center of die 10 can be decided at a position at a constant current value of bottom dead center sensor 11. Temperature sensor 12 detects the rise in temperature due to molding of die 10. It is used to correct for the temperature drift generated on the detected value of the bottom dead center detection sensor 11 due to a temperature rise. Although the bottom dead center detection sensor 11 measures the distance between upper mold 10A and lower mold 10B by detecting the over current generated when upper mold 10A approaches lower mold 10B, it has the defect of being an analog system. As described above, corrections for temperature drift and for changes over time become necessary. When using an optical linear scale of a detection value (normally in 0.5-0.1 microns detection units) of slide position detection device 9, the output value of bottom dead center detection device 9, the output value of bottom dead center detection device 9 is compared, and the failure of analog type bottom dead center detection sensor 11 when it is approaching the die and the detection value of slide position detection sensor 11 is determined.

[0025] With regard to die 10 which may have different deformations in different parts because of molding, a plurality of bottom dead center detection sensors 11 can be built in. An average value from these detection values is then calculated.

[0026] Furthermore, bottom dead center detection sensor 11 can be provided on upper mold 10A.

[0027] Each of the detection values from slide position detection device 9, bottom dead center detection sensor 11, and temperature sensor 12 are inputted into NC control device 6.

[0028] Referring to Fig. 2, the control system for the above construction is shown as a block diagram.

[0029] NC control device 6 is provided with an NC device 6A and a driver 6B. The detection values from current detection device 8, bottom dead center sensor 11, temperature sensor 12, and slide position detection device 9 are fed back to NC device 6A and converted to numerical values. These are mathematically operated and used in the control.

[0030] The necessary data is saved in memory and reproduced and used.

[0031] Normally, when slide 3 is moved up and down, a slide motion, in which the top dead center and the bottom dead center are decided on NC device 6A in advance, is set. A set command value is outputted from NC device 6A at a constant time interval. Driver 6B outputs a current value corresponding to the command value, and this is supplied to servo motor 5.

[0032] Vertical motion of slide 3 is conducted by the rotation of servo motor 5. The slide motion is controlled by the detection values of the top dead center and bottom dead center detected by slide position detection device 9.

[0033] Next, molding is conducted, and when the molded product of the required precision is achieved, the value of the bottom dead center detected by bottom dead center detection sensor 11 is saved in NC device 6A as the bottom dead center correction amount. The determination of the bottom dead center correction amount is conducted by switching on a correction initiation switch (not shown), which is provided on NC device 6A. An average value from a certain number (set in advance) of molding samplings is saved as the bottom dead center correction amount.

[0034] Based on the saved bottom dead center correction amount, the bottom dead center position of the slide motion, which has been set in advance, is corrected.

[0035] The bottom dead center correction amount can be displayed as a numerical value on a setting device not shown.

[0036] A maximum correction amount is determined as the maximum value for correction in order to prevent the breaking of the die. The bottom dead center correction amount is controlled by NC device 6A so that is does not exceed this value.

[0037] When molding is continued, a temperature rise is generated in die 10. Based on the temperature measurement value detected by temperature sensor 12, there is correction for the amount of temperature drift of bottom dead center detection sensor 11.

[0038] The temperature drift is measured in advance for each bottom dead center detection sensor 11 and is added to the actual bottom dead center correction amount.

[0039] Referring to Fig. 6, the bottom dead center of slide 3, which moves up and down by the command value of the set slide motion, is controlled by feed back of the bottom dead center position of the slide detected by slide position detection device 9. This slide motion of slide 3 is shown as the solid line of the pre-correction slide motion 13. The bottom dead center correction amount obtained by detections from bottom dead center detection sensor 11 and temperature sensor 12 provided on die 10 and lower mold 10B is added to pre-correction slide motion 13. The corrected slide motion is displayed as a dotted line of corrected slide motion 14.

[0040] The bottom dead center of pre-correction slide motion 13 is controlled by the detection value from slide position detector 9. As a result, it is correct for fluctuations of the bottom dead center from the distortions in frame 2 and the fluctuations in the bottom dead center due to heat generation in the servo press machine parts. As described above, the bottom dead center precision is 5-10 micrometers.

[0041] The bottom dead center precision of corrected slide motion 14, which is corrected by the bottom dead center correction amount obtained from bottom dead detection sensor 11 provided on die 10, is in 1 micron unit.

[0042] Referring to Fig. 5, the mode of the construction of servo press machine 1 is shown. With slide 3, guide rods 31, which are erected on the lower surface four comers, are guided in the vertical direction by guides 32 of frame 2.

[0043] Timing pulley 14, which is fastened to male screw member 4, is connected to timing pulley 15 and timing belt 16, which are provided on the output shaft of servo motor 5 which is fastened to frame 2.

[0044] An encoder 17 is connected directly with servo motor 5 and is used in rotation control of servo motor 5. The rotation angle signal from encoder 17 is fed back to NC device 16 and used in rotation control of the servo motor.

[0045] On the part of frame 2 adjacent to slide 3, a vertically disposed slide position detection device 9 of a linear scale is mounted.

[0046] The opposing die molds 10A and 10B are attached to slide 3 and bolster 21.

[0047] As is clear from the above description, according to the present invention, because a bottom dead center detection sensor is provided on the die, a bottom dead center precision of 1 micron unit which could not be achieved in the prior art is achieved. A temperature sensor is provided on the die, and temperature drift of the bottom dead center detection sensor due to the temperature rise from molding can also be detected.

[0048] Furthermore, the correction by the bottom dead center detection sensor can be confirmed by conducting measurement of the bottom dead center correction amount anytime during molding. As a result, the bottom dead center precision can be easily maintained.

[0049] Referring to Figs. 3 and 4, a second embodiment of the present invention of a device for correcting the bottom dead center by detecting the load of a servo press is described.

[0050] Referring to Fig. 4, a control system for servo motor 5 which controls the ascending and descending motion of slide 3 is shown. NC control device 6 is constructed from the following: a NC device 6A, which outputs pre-set NC signals; and a driver 6B, which outputs a current corresponding to the NC signals outputted from NC device 6A and drives and controls servo motor 5.

[0051] In addition, there is feedback to NC device 6A of signals indicating the current value, which represents the slide load detected by current detection device 8, and the slide position, which is detected by scale detection 9. By conducting calculations with these values, a correction value is obtained and is outputted as a NC signal. A current corresponding to this NC signal is outputted to driver 6B and is used in the rotation control of servo motor 5.

[0052] The molding load of slide 3 can be calculated by the following method: a distortion measure is attached to frame 2; and the distortion measure output resulting from the load during molding is inputted into NC device 6A. The molding load can be detected by other methods as well.

[0053] In addition, a die upper mold of 10A is attached to the lower surface of slide 3. A die lower mold 10B is attached to the upper surface of a bolster, which has been mounted on top of a bed of frame 2. The touch point is where die upper mold 10A reaches the processing material, which has been supplied on top of die lower mold 10B. At this touch point, a rise in the current value due to the initiation of molding is detected by current detection device 8. This is inputted into NC device 6A and is used in the rotation control of servo motor 5.

[0054] Details of the bottom dead center correction with the second embodiment now will be described. In the first bottom dead center correction method by the detection of the load with respect to the changes in the hardness of the processing material, first, slide 3 is lowered, and molding is initiated. When the load value of slide 3, as calculated by NC device 6A, reaches a pre-set load value, the slide position detected by scale detection device 9 and a pre-set slide position are compared.

[0055] If the detected slide position is higher than the pre-set position, the hardness of the processing material is determined to be higher than the standard hardness. The difference in the slide position corresponding to the difference with the standard value of hardness, is detected, and the set bottom dead center of slide 3 is corrected so that it is lower, and molding is conducted by lowering slide 3 to the corrected bottom dead center. Furthermore, correction values are determined by data obtained beforehand by molding processing materials having a standard value of hardness and materials having values different from the standard value. These are saved in NC device 6 and used for the pre-set load value and slide position.

[0056] Conversely, when the slide position is lower than the pre-set position, the hardness of the processing material is determined to be lower than the standard hardness. The difference in the slide position, corresponding to the difference with the standard value of hardness, is detected, and the set bottom dead center of slide 3 is corrected so that it is higher, and molding is conducted by lowering slide 3 to the corrected bottom dead center. The correction value of the bottom dead center corresponding to the difference with the standard value of hardness is determined as described previously by data obtained by molding processing materials having a standard value of hardness and materials having values different from the standard value. With this correction, the bottom dead center precision of slide 3 can be in the range of one to a few microns.

[0057] The standard hardness of the processing material is determined to be the hardness of an approximately uniform portion in the middle of the coil. A hardness is determined to be higher or lower. As described previously, the bottom dead center correction value, which responds to the fluctuation in the load value due to differences in hardness, is determined by data obtained beforehand by molding processing materials with a standard value of hardness and materials of a hardness different from the standard value. With this correction, the bottom dead center precision of a slide 3 can be in the range of one to a few microns.

[0058] We have stated up to this point that the thickness of the processing material is uniform, but the thickness of the coil material can change some. If the thickness changes, the molding load values at the same bottom dead center position can fluctuate. First, during the lowering of slide 3, the touch point, which is the point where upper mold 10A reaches the processing material supplied on top of lower mold 10B, is detected by current detection device 8 as a rise in the current value due to the initiation of molding.

[0059] At this time, if the slide position detected by scale detection device 9 is the standard value, or in other words, if the thickness is the standard value, the set bottom dead center of slide 3 is not corrected, and molding is conduced by lowering slide 3 to the pre-set bottom dead center. On the other hand, if the slide position is higher than the standard value, the thickness is determined to be thick. The set bottom dead center of slide 3 is corrected, and molding is conducted by lowering slide 3 to a corrected set bottom dead center. Conversely, if the slide position is lower than the standard value, the thickness is determined to be thin, and the set bottom dead center of slide 3 is corrected, and molding is conducted by raising slide 3 to the corrected set bottom dead center.

[0060] The correction of the set bottom dead center due to changes in thickness of the processing material can be used in combination with one of either the first or second method for bottom dead center correction by detecting a load in response to changes in the hardness of the processing material. Therefore, a combination can be selected and used by a setting device provided on NC control device 6 of servo press 1.

[0061] Referring to Fig. 6, a slide motion from the lowering to the raising of slide 3 is shown. The X-axis is the time axis (SEC), and the Y-axis is the slide position axis (MM). The curve shown as the pre-correction slide motion is the curve of the prior art example with a bottom dead center precision of 5-10 microns.

[0062] When correcting by detection of a load in response to changes in the hardness of the processing material and correcting for thickness, the curve of the slide motion becomes the curve shown by the dotted line. Therefore, as described above, with these corrections, the bottom dead center precision is improved and is in the range of one to a few microns. The correction amount is displayed on the screen as the "current correction value".

[0063] In the bottom dead center correction device of the prior art, the set bottom dead center is corrected by detecting the fluctuation of the slide position, and the bottom dead center precision is 5-10 microns. In contrast, as is clear from the above description, according to the present invention, by correcting the set bottom dead center by the fluctuation in the molding load, fluctuations in the set bottom dead center due to deformation of all of the construction parts, which includes not only the servo press but also the die, can be corrected. There are considerable advantages to improving the bottom dead center precision to a range of 1 to a few microns.

[0064] Having described preferred embodiments of the present invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments, and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope of the invention as defined in the appended claims.

Claims

1. A servo press machine (1) including a servo motor (5) as a drive source therefor; a press slide (3) operating between a top dead centre position and a bottom dead centre position; and a bottom dead centre correction device comprising:

(a) a scale detection device (9), which detects a position of said slide in a vertical direction and which outputs an electrical position signal;

(b) a current detection device (8), which detects a current indicative of molding load supplied to said servo motor;
an NC control device (6), which controls a rise and fall motion of said slide by controlling said current that is supplied to said servo motor so that it corresponds to a pre-set slide motion;

characterised in that when a slide load value, which is calculated from the current supplied to the servo motor and is inputted from said current detection device, reaches a set slide load value during moulding, said NC control device corrects a set bottom dead centre of said slide according to a position correction value, which is a difference between the slide position and a set slide position value, wherein the set slide load value and set slide position value are previously obtained by moulding processing-materials of various hardness.

2. A servo press as claimed in Claim 1, wherein:

when said slide load value, which is calculated by said NC control device, reaches said set slide load value, if said slide position, which is outputted from said

scale detection device, is higher than said set slide position value, the material to be processed is determined to have a high hardness, and said set bottom dead centre of said slide is corrected downward by an amount of said position correction value, and said slide is lowered;

conversely, if said position is lower than said set slide position value, the processing material is determined to have a low hardness, and said set bottom dead centre of said slide is corrected upward by an amount of said position correction value, and said slide is lowered.

3. A servo press as claimed in Claim 1 or claim 2, wherein:

a touch point, where an upper mould (10A) which is lowered together with said slide contacts a processing material supplied onto a lower mould (10B), is detected by a rise in said load current outputted from said current detection device;

when said touch points is detected, a corrected value for a set bottom dead centre of said slide obtained from an output of said scale detection device can be corrected.

4. A servo press as claimed in Claim 1, Claim 2 or Claim 3, further comprising:

a load detection cell which detects said slide load value;

when said slide load value, which is detected by said load detection cell, reaches said set slide load value, said NC control device corrects said set bottom dead centre of said slide according to said position correction value.

5. A servo press as described in any preceding claim, wherein:

when said slide position, which is outputted from said scale detection device, reaches a set slide position value, if said load value, which is calculated by said NC control device, is larger than said set slide load value, the material to be processed is determined to have a high hardness, and a set bottom dead centre of said slide is corrected downward by an amount of said load correction value, and said slide is lowered;

conversely, if said load value is lower than said set slide load value, the processing material is determined to have a low hardness, and a set bottom dead centre of said slide is corrected upward by an amount of said load correction value, and said slide is lowered.

Ansprüche

1. Servopresse (1) mit einem Servomotor (5) als Antriebsquelle; einem Pressenstößel (3), der zwischen einer oberen Totpunktlage und einer unteren Totpunktlage arbeitet; und einer Vorrichtung zur Korrektur des unteren Totpunkts, umfassend:

(a) eine Größenerfassungsvorrichtung (9), welche die Lage des Stößels in senkrechter Richtung erfasst und ein elektrisches Lagesignal ausgibt;

(b) eine Stromerfassungsvorrichtung (8), welche einen Strom erfasst, der eine dem Servomotor zugeführte Formungslast anzeigt;
einer NC-Steuervorrichtung (6), die eine Aufstiegs- und Fallbewegung des Stößels steuert, indem sie den dem Servomotor zugeführten Strom so steuert, dass er einer vorgegebenen Stößelbewegung entspricht;

dadurch gekennzeichnet, dass, wenn ein aufgrund des dem Servomotor zugeführten und von der Stromerfassungsvorrichtung eingegebenen Stroms errechneter Stößellastwert während des Formungsvörgangs einen eingestellten Stößellastwert erreicht, die NC-Steuervorrichtung einen eingestellten unteren Totpunkt des Stößels korrigiert, und zwar gemäß einem Lagekorrekturwert, der die Differenz zwischen der Stößellage und einem eingestellten Stößellagewert ist, wobei der eingestellte Stößellastwert und der eingestellte Stößellagewert zuvor durch Formung von Verarbeitungsmaterial verschiedener Härte gewonnen werden.

2. Servopresse gemäß Anspruch 1, bei der,
wenn der durch die NC-Steuervorrichtung errechnete Stößellastwert den einstellten Stößellastwert erreicht, im Falle, dass die von der Größenerfassungsvorrichtung ausgegebene Stößellage höher ist als der eingestellte Stößellagewert, festgestellt wird, dass das zu verarbeitende Material von hoher Härte ist, und der eingestellte untere Totpunkt des Stößels um den Betrag des Lagekorrekturwerts nach unten korrigiert wird und der Stößel abgesenkt wird;
im umgekehrten Fall, wenn die Lage niedriger ist als der eingestellte Stößellagewert, festgestellt wird, dass das zu verarbeitende Material von geringer Härte ist, und der eingestellte untere Totpunkt des Stößels um den Betrag des Lagekorrekturwerts nach oben korrigiert wird und der Stößel abgesenkt wird.

3. Servopresse gemäß Anspruch 1 oder Anspruch 2, bei der
ein Aufsetzpunkt, an dem eine zusammen mit dem Stößel abgesenkte obere Form (10A) mit einem einer unteren Form (10B) zugeführten zu verarbeitenden Material in Kontakt kommt, erfasst wird durch einen Anstieg des von der Stromerfassungsvorrichtung ausgegebenen Laststroms;
wenn der Aufsetzpunkt erfasst wird, ein korrigierter Wert für einen durch eine Ausgabe der Größenerfassungsvorrichtung gewonnenen eingestellten unteren Totpunkt des Stößels korrigiert werden kann.

4. Servopresse gemäß Anspruch 1, Anspruch 2 oder Anspruch 3, ferner umfassend:

eine Lasterfassungszelle, welche den Stößellastwert erfasst;

die Tatsache, dass, wenn der von der Lasterfassungszelle erfasste Stößellastwert den eingestellten Stößellastwert erreicht, die NC-Steuervorrichtung den einstellten unteren Totpunkt des Stößels gemäß dem Lagekorrekturwert korrigiert.

5. Servopresse, wie in einem der vorhergehenden Ansprüche beschrieben, bei der, wenn die von der Größenerfassungsvorrichtung ausgegebene Stößellage einen eingestellten Stößellagewert erreicht, im Falle, dass der von der NC-Steuervorrichtung errechnete Lastwert größer ist als der eingestellte Stößellastwert, festgestellt wird, dass das zu verarbeitende Material von hoher Härte ist, und der eingestellte untere Totpunkt des Stößels um den Betrag des Lagekorrekturwerts nach unten korrigiert wird und der Stößel abgesenkt wird;
im umgekehrten Fall, wenn der Lastwert niedriger ist als der eingestellte Stößellastwert, festgestellt wird, dass das zu verarbeitende Material von geringer Härte ist, und ein eingestellter unterer Totpunkt des Stößels um den Betrag des Lastkorrekturwerts nach oben korrigiert wird und der Stößel abgesenkt wird.

Revendications

1. Presse asservie (1), comprenant un servomoteur (5) en tant que source d'entraînement pour celui-ci, un coulisseau de presse (3) se déplaçant entre une position de point mort haut et une position de point mort bas, et un dispositif de correction de point mort bas comprenant :

(a) un dispositif de détection de graduation (9) qui détecte une position dudit coulisseau dans une direction verticale et qui fournit en sortie un signal électrique de position,

(b) un dispositif de détection de courant (8) qui détecte un courant indicatif d'une charge de moulage, fourni audit servomoteur,
un dispositif de commande NC (6) qui commande un mouvement de montée et de chute dudit coulisseau en commandant ledit courant qui est fourni audit servomoteur de sorte qu'il corresponde à un mouvement de coulissement préétabli,

caractérisée en ce que, lorsqu'une valeur de charge de coulisseau, qui est calculée à partir du courant fourni au servomoteur et est reçue en entrée dudit dispositif de détection de courant, atteint une valeur de charge de coulisseau de consigne au cours du moulage, ledit dispositif de commande NC corrige un point mort haut de consigne dudit coulisseau conformément à une valeur de correction de position, qui est une différence entre la position du coulisseau et une valeur de position de coulisseau de consigne, où la valeur de charge de coulisseau de consigne et la valeur de position de coulisseau de consigne sont précédemment obtenues par le moulage de matériaux de traitement de diverses duretés.

2. Presse asservie selon la revendication 1, dans laquelle :

lorsque ladite valeur de charge de coulisseau, qui est calculée par ledit dispositif de commande NC, atteint ladite valeur de charge de coulisseau de consigne, si ladite position de coulisseau, qui est fournie en sortie dudit dispositif de détection de graduation est supérieure à ladite valeur de position de coulisseau de consigne, le matériau à traiter est déterminé comme ayant une dureté élevée, et ledit point mort bas de consigne dudit coulisseau est corrigé vers le bas d'une quantité égale à ladite valeur de correction de position et ledit coulisseau est abaissé,

inversement, si ladite position est inférieure à ladite valeur de position de coulisseau de consigne, le matériau de traitement est déterminé comme ayant une dureté faible, et ledit point mort bas de consigne dudit coulisseau est corrigé vers le haut d'une quantité égale à ladite valeur de correction de position, et ledit coulisseau est abaissé.

3. Presse asservie selon la revendication 1 ou la revendication 2, dans laquelle :

un point de contact, où un moule supérieur (10A) qui est abaissé avec ledit coulisseau vient en contact avec un matériau de traitement disposé sur un moule inférieur (10B), est détecté par une augmentation dudit courant de charge fourni en sortie dudit dispositif de détection de courant,

lorsque ledit point de contact est détecté, une valeur corrigée pour un point mort bas de consigne dudit coulisseau obtenue à partir d'une sortie dudit dispositif de détection de graduation peut être corrigée.

4. Presse asservie selon la revendication 1, la revendication 2 ou la revendication 3, comprenant en outre :

une cellule de détection de charge qui détecte ladite valeur de charge de coulisseau,
lorsque ladite valeur de charge de coulisseau, qui est détectée par ladite cellule de détection de charge, atteint ladite valeur de charge de coulisseau de consigne, ledit dispositif de commande NC corrige ledit point mort bas de consigne dudit coulisseau conformément à ladite valeur de correction de position.

5. Presse asservie selon l'une quelconque des revendications précédentes, dans laquelle :

lorsque ladite position de coulisseau, qui est fournie en sortie dudit dispositif de détection de graduation atteint une valeur de position de coulisseau de consigne, si ladite valeur de charge, qui est calculée par ledit dispositif de commande NC, est supérieure à ladite valeur de charge de coulisseau établie, le matériau à traiter est déterminé comme ayant une dureté élevée, et un point mort bas de consigne dudit coulisseau est corrigé vers le bas d'une quantité égale à ladite valeur de correction de charge, et ledit coulisseau est abaissé,
inversement, si ladite valeur de charge est inférieure à ladite valeur de charge de coulisseau de consigne, le matériau de traitement est déterminé comme ayant une faible dureté et un point mort bas de consigne dudit coulisseau est corrigé vers le haut d'une quantité égale à ladite valeur de correction de charge et ledit coulisseau est abaissé.

Drawing