1. Field of the Invention
This invention relates to a press machine controller for controlling a press machine including a servo motor which drives a slide via a reduction mechanism with the reduction ratio changed in accordance with the position of the slide.
2. Description of the Related Art
Conventionally, a mechanical press in which press forming time can be shortened by operating a slide at high speed can be used as a press machine. Japanese Unexamined Patent Publication No. 10-249590 discloses a mechanical press having a link mechanism. The slide of the press machine disclosed in Japanese Unexamined Patent Publication No. 10-249590 moves up and down with the motion of a servo motor transmitted through a link mechanism.
In the press machine disclosed in Japanese Unexamined Patent Publication No. 10-249590, the reduction ratio of the link mechanism for the motor is changed in accordance with the position of the slide. Specifically, the reduction ratio is maximized when the slide reaches the bottom dead center, and at this point, the largest torque is required for the motor.
In the case where the slide simply continues to move through the bottom dead center, the inertia of the motor and the dynamic friction acting on the link mechanism, etc., eliminate the need of a large torque.
However, in the case where the press machine is stopped with the slide located at the bottom dead center for the purpose of confirming the operation of the press machine or otherwise, the inertial force fails to work and the static friction acts on the link mechanism, etc. Therefore, a large torque is required to restart the press machine.
In order to generate a large torque normally not required, the size of the servo motor of the press machine has to be large. However, a large servo motor is expensive, resulting in increased production cost of the press machine.
This invention has been achieved in view of this situation, and the object thereof is to provide a press machine controller whereby the press machine, even if stopped with the slide located at the bottom dead center, can be restarted with a small torque.
According to a first aspect of the invention, there is provided a press machine controller for controlling a press machine having a servo motor to drive a slide via a reduction mechanism adapted to be changed in reduction ratio in accordance with a position of the slide, comprising: a command generator for generating at least one of a position command, a speed command and a torque command for the servo motor; a vibration command generator for generating a vibration command based on a parameter preset for the press machine controller; a slide position detector for detecting the position of the slide; and a vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the servo motor in a case where the slide position detected by the slide position detector is in a predetermined range.
According to a second aspect of the invention, there is provided a press machine controller for controlling a press machine having first and second servo motors to drive a slide via first and second reduction mechanisms, respectively, adapted to be changed in reduction ratio in accordance with a position of the slide, comprising: a first command generator for generating at least one of a position command, a speed command and a torque command for the first servo motor; a second command generator for generating at least one of a position command, a speed command and a torque command for the second servo motor; a vibration command generator for generating a vibration command based on a parameter preset for the press machine controller; a slide position detector for detecting the position of the slide; a first vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the first servo motor in a case where the slide position detected by the slide position detector is in a predetermined range; and a second vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the second servo motor in a case where the slide position detected by the slide position detector is in the predetermined range; wherein the vibration command added by the first vibration command adding portion is in phase with the vibration command added by the second vibration command adding portion.
According to a third aspect of the invention, there is provided a press machine controller for controlling a press machine having a servo motor to drive a slide via a reduction mechanism adapted to be changed in reduction ratio in accordance with a position of the slide, comprising: a command generator for generating at least one of a position command; a speed command and a torque command for the servo motor; a vibration command generator for generating a vibration command based on a parameter preset for the press machine controller; a vibration adding signal detector for detecting an input of a vibration adding signal permitting an addition of the vibration command; and a vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the servo motor in a case where the vibration adding signal is input.
According to a fourth aspect of the invention, there is provided a press machine controller for controlling a press machine having first and second servo motors for driving a slide via first and second reduction mechanisms, respectively, adapted to be changed in reduction ratio in accordance with a position of the slide, comprising: a first command generator for generating at least one of a position command, a speed command and a torque command for the first servo motor; a second command generator for generating at least one of a position command, a speed command and a torque command for the second servo motor; a vibration command generator for generating a vibration command based on a parameter preset for the press machine controller; a vibration adding signal detector for detecting an input of a vibration adding signal permitting an addition of the vibration command; a first vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the first servo motor in a case where the vibration adding signal is input; and a second vibration command adding portion for adding the vibration command to any one of the position command, the speed command and the torque command for the second servo motor in a case where the vibration adding signal is input; wherein the vibration command added by the first vibration command adding portion is in phase with the vibration command added by the second vibration command adding portion.
According to a fifth aspect of the invention, there is provided a press machine controller according to any one of the first to fourth aspects, wherein the parameter is included in an external device connected to the press machine controller.
These and other objects, features and advantages of the present invention will be more apparent in light of the detailed description of exemplary embodiments thereof as illustrated by the drawings.
a is an enlarged view of a slide and a link mechanism with the slide having reached the top dead center.
b is another enlarged view of the slide and the link mechanism with the slide having reached the bottom dead center.
The embodiments of the invention are explained below with reference to the accompanying drawings. In the drawings, the same member is designated with a similar reference numeral. To facilitate understanding, the scale of each drawing has been appropriately changed.
a and 2b are enlarged views of the slide and the link mechanism with the slide having reached the top and bottom dead centers, respectively. As shown in
A small pulley 33 is mounted on the output shaft 43 of a servo motor 41. The small pulley 33 and the large pulley 34 are wound with a common belt 35. As a result, the rotational motion of the output shaft 43 of the servo motor 41 is reduced in speed and transmitted to the large pulley 34, and converted to the linear motion of the slide 38 by the rod 36 and the link mechanism 37. As a result, the slide 38 moves up and down relatively to the bolster 39. Incidentally, a position detector 42 for detecting the position of the output shaft 43 is mounted on the servo motor 41. The position detector 42 is, for example, a rotary encoder.
Referring to
As can be seen from
Incidentally, the condition setting unit 11 is not necessarily included in the press machine controller 10. As indicated by dashed line in
Then, the speed feedback data generated based on the change in the position feedback data, within a predetermined time, detected by the position detector 42 is subtracted from the speed command CV thereby to calculate a speed deviation. This speed deviation is input to a speed control portion 16. The speed control portion 16 outputs a torque command CT (current command) based on the speed deviation. In
First, in step 101 shown in
Then, the process proceeds to step 103, in which the vibration command generator 13 (see
T=A·sin(2πft)
where t is the time.
Then, in step 104, the slide position detector 12 of the press machine controller 10 detects the present position PO of the slide 38 with respect to the fixing unit 31. Specifically, the position PO of the slide 38 is determined using the position feedback from the position detector 42. As an alternative, the position of the slide 38 may be detected directly using a limit switch 45 arranged on the slide 38 or a linear scale 46 (see
Step 105 judges whether the position PO of the slide 38 is located between the predetermined positions P1 and P2. In the case where the position PO of the slide 38 is located between the predetermined positions P1 and P2, the process proceeds to step 106.
In step 106, the micro vibration command T is added to the torque command CT calculated by the speed control portion 16. Specifically, the vibration command adding portion 23 shown in
On the contrary, in the case where step 105 judges that the position PO of the slide 38 is not located between the predetermined positions P1 and P2, the process proceeds to step 107, in which the very torque command CT is employed as the final torque command and the process is ended.
Incidentally, according to the embodiment explained with reference to
As described above, according to this invention, the vibration command T is added to any of the position command CP, the speed command CV and the torque command CT for the servo motor in the case where the slide 38 is located at the bottom dead center or in the vicinity of the bottom dead center. As a result, the slide 38 is vibrated slightly.
As a result, the dynamic friction works at the time of restarting the press machine 30. In other words, according to this invention, no static friction acts on the slide 38, etc., at the time of restarting the press machine 30. For this reason, the press machine 30 can be restarted with a small torque. Consequently, the press machine 30 according to the invention can employ a small servo motor, thereby making it possible to reduce the production cost of the press machine 30.
In the case where a specific workpiece (not shown) is pressed by the press machine 30, the timing of adding the vibration command (slide position) may be desirably changed according to the workpiece. According to another embodiment shown in
As shown in
As can be seen from
In such a case, the position at which the vibration is started can be changed as desired by the operator. Therefore, in pressing a specified workpiece in the press machine 30, the vibration command can be added at the slide position most suitable for the workpiece, thereby making it possible to perform the press machining operation optimally.
In the second embodiment, a similar process to the process described with reference to
Even in the case where the vibration command T is added to the position command CP or the speed command CV, though not shown in
In this configuration, at the time of restarting the press machine 30, forces are exerted on the slide 38 at the same timing from the first servo motor 41a and the second servo motor 41b via the link mechanisms 37a, 37b, respectively. Therefore, it will be understood, that according to the second embodiment, the press machine 30 can be restarted in stable fashion. The embodiments described above can of course be combined with each other.
According to the first aspect of the invention, the vibration command is added to any one of the position command, the speed command and the torque command of the servo motor. Therefore, the press machine, even if stopped with the slide at the bottom dead center, can be restarted under dynamic friction. As a result, the press machine can be restarted with a small torque. This makes it possible to employ a compact servo motor, with the result that the production cost of the press machine is suppressed. Incidentally, the reduction mechanism is a link mechanism, for example.
According to the second aspect of the invention, a similar effect to the first aspect can be obtained. Further, according to the second aspect, the phase added to the first servo motor side is identical with the phase added to the second servo motor side, and therefore, the timing lag which otherwise might occur between the forces applied from the first and second servo motors to the slide via the reduction mechanism at the time of restarting the press machine, can be avoided. Thus, the press machine can be restarted in stable fashion.
According to the third aspect of the invention, the vibration can be added at an arbitrary timing considered as required by the operator to add the vibration command.
According to the fourth aspect of the invention, the vibration can be added at an arbitrary timing considered as required by the operator to add the vibration command.
According to the fifth aspect of the invention, an external device containing a given parameter can be easily replaced by another external device containing another parameter.
Although the invention has been shown and described with exemplary embodiments thereof, it should be understood by those skilled in the art that the foregoing and various other changes, omissions and additions may be made therein and thereto without departing from the scope of the invention.
Number | Date | Country | Kind |
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2009-161086 | Jul 2009 | JP | national |