Device and method of controlling machine tool, to control synchronized operation of spindle axis and feed axis
First Claim
1. A controller of a machine tool, the controller being configured to control a synchronized operation of a spindle axis and a feed axis of the machine tool, the controller comprising:
- a hardware configured as;
a numerical control section configured to prepare a spindle-axis command and a feed-axis command based on a tapping program;
a spindle-axis control section configured to control a rotational motion of the spindle axis in accordance with the spindle-axis command;
a rotation detecting section configured to detect a rotational position of the spindle axis; and
a feed-axis control section configured to control a feed motion of the feed axis in accordance with the feed-axis command, based on the rotational position;
the numerical control section comprising;
a spindle-axis command outputting section configured to obtain, from the tapping program, a total rotation amount and a maximum rotation speed of the spindle axis during a period when the spindle axis operates from a starting position to a target position, and to send the total rotation amount and the maximum rotation speed as the spindle-axis command to the spindle-axis control section;
the spindle-axis control section comprising;
an initial-motion control section configured to make the spindle axis perform an accelerated rotation at maximum capacity from the starting position, by a velocity control in which the maximum rotation speed is set as a target value;
a maximum-acceleration detecting section configured to detect a maximum acceleration of the spindle axis during the accelerated rotation at maximum capacity, based on the rotational position;
a residual rotation-amount detecting section configured to detect a residual rotation amount of the spindle axis during a period when the spindle axis operates from a current position to the target position, based on the total rotation amount and the rotational position;
a current-speed detecting section configured to detect a current speed of the spindle axis based on the rotational position;
a decelerating-motion control section configured to execute a velocity control for making the spindle axis perform a decelerated rotation so as to reach a predetermined intermediate speed, based on the residual rotation amount and the current speed, after the accelerated rotation at maximum capacity;
a positioning-motion control section configured to execute a position control for making the spindle axis perform a decelerated rotation at a maximum deceleration corresponding to the maximum acceleration so as to reach the target position, based on the residual rotation amount and the current speed, after the spindle axis reaches the intermediate speed; and
a torque-command limiting section configured to limit a fluctuation of a torque command of the position control, instructed from the positioning-motion control section to the spindle axis, to a predetermined range over a time period from a point when the spindle axis reaches the intermediate speed to a point when a predetermined elapse condition is satisfied.
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Abstract
A controller for controlling a synchronized operation of spindle and feed axes. A spindle-axis control section includes an initial-motion control section for accelerating a spindle axis from a starting position; a maximum-acceleration detecting section for detecting a maximum acceleration of the spindle axis during acceleration; a residual rotation-amount detecting section for detecting a residual rotation amount of the spindle axis; a current-speed detecting section for detecting a current speed of the spindle axis; a decelerating-motion control section for decelerating the spindle axis to reach an intermediate speed, after the acceleration; a positioning-motion control section for decelerating the spindle axis to reach the target position after reaching the intermediate speed; and a torque-command limiting section for limiting a fluctuation of a torque command of the position control, instructed to the spindle axis, to a predetermined range over a period until a predetermined elapse condition is satisfied after reaching the intermediate speed.
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Citations
13 Claims
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1. A controller of a machine tool, the controller being configured to control a synchronized operation of a spindle axis and a feed axis of the machine tool, the controller comprising:
a hardware configured as; a numerical control section configured to prepare a spindle-axis command and a feed-axis command based on a tapping program; a spindle-axis control section configured to control a rotational motion of the spindle axis in accordance with the spindle-axis command; a rotation detecting section configured to detect a rotational position of the spindle axis; and a feed-axis control section configured to control a feed motion of the feed axis in accordance with the feed-axis command, based on the rotational position; the numerical control section comprising; a spindle-axis command outputting section configured to obtain, from the tapping program, a total rotation amount and a maximum rotation speed of the spindle axis during a period when the spindle axis operates from a starting position to a target position, and to send the total rotation amount and the maximum rotation speed as the spindle-axis command to the spindle-axis control section; the spindle-axis control section comprising; an initial-motion control section configured to make the spindle axis perform an accelerated rotation at maximum capacity from the starting position, by a velocity control in which the maximum rotation speed is set as a target value; a maximum-acceleration detecting section configured to detect a maximum acceleration of the spindle axis during the accelerated rotation at maximum capacity, based on the rotational position; a residual rotation-amount detecting section configured to detect a residual rotation amount of the spindle axis during a period when the spindle axis operates from a current position to the target position, based on the total rotation amount and the rotational position; a current-speed detecting section configured to detect a current speed of the spindle axis based on the rotational position; a decelerating-motion control section configured to execute a velocity control for making the spindle axis perform a decelerated rotation so as to reach a predetermined intermediate speed, based on the residual rotation amount and the current speed, after the accelerated rotation at maximum capacity; a positioning-motion control section configured to execute a position control for making the spindle axis perform a decelerated rotation at a maximum deceleration corresponding to the maximum acceleration so as to reach the target position, based on the residual rotation amount and the current speed, after the spindle axis reaches the intermediate speed; and a torque-command limiting section configured to limit a fluctuation of a torque command of the position control, instructed from the positioning-motion control section to the spindle axis, to a predetermined range over a time period from a point when the spindle axis reaches the intermediate speed to a point when a predetermined elapse condition is satisfied.
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2. The controller of claim 1, wherein the decelerating-motion control section is configured to successively update a velocity command for the decelerated rotation with use of the residual rotation amount and the current speed, and to make the spindle axis perform the decelerated rotation by the successively updated velocity command so that the residual rotation amount at an instant when the spindle axis reaches the intermediate speed becomes equal to a positioning rotation amount of the spindle axis required for the spindle axis to reach the target position under the position control.
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3. The controller of claim 1, wherein the torque-command limiting section is configured to further limit a fluctuation of a torque command of the velocity control, instructed from the decelerating-motion control section to the spindle axis, to a predetermined range over the time period.
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4. The controller of claim 1, wherein the elapse condition comprises at least one of a condition where a predetermined time has elapsed, a condition where the current speed has decreased to a predetermined speed or below, and a condition where the residual rotation amount has decreased to a predetermined rotation amount or below.
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5. The controller of claim 1, wherein the starting position corresponds to a process start position of a tapping process, and wherein the target position corresponds to a target thread depth of the tapping process.
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6. The controller of claim 5, wherein the positioning-motion control section is configured to make the spindle axis stop at the target thread depth.
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7. The controller of claim 5, wherein the positioning-motion control section is configured not to make the spindle axis stop at the target thread depth but to make the spindle axis perform, by a position control, an accelerated inverse rotation at a maximum acceleration of inverse rotation, which is identical to the maximum deceleration, to an initial return position at which the spindle axis has returned by a predetermined rotation number from the target thread depth, after the spindle axis reaches the target thread depth.
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8. The controller of claim 1, wherein the starting position corresponds to a target thread depth of a tapping process, and wherein the target position corresponds to a return completion position of the tapping process.
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9. A method of controlling a machine tool, configured to control a synchronized operation of a spindle axis and a feed axis, the method comprising the steps, executed by a controller, of:
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obtaining, from a tapping program, a total rotation amount and a maximum rotation speed of the spindle axis during a period when the spindle axis operates from a starting position to a target position; making the spindle axis perform an accelerated rotation at maximum capacity from the starting position, by a velocity control in which the maximum rotation speed is set as a target value; detecting a maximum acceleration of the spindle axis during the accelerated rotation at maximum capacity, based on a rotational position feedback of the spindle axis; detecting a residual rotation amount of the spindle axis during a period when the spindle axis operates from a current position to the target position, based on the total rotation amount and the rotational position feedback; detecting a current speed of the spindle axis based on the rotational position feedback; executing a velocity control for making the spindle axis perform a decelerated rotation so as to reach a predetermined intermediate speed, after the accelerated rotation at maximum capacity; executing a position control for making the spindle axis perform a decelerated rotation at a maximum deceleration corresponding to the maximum acceleration so as to reach the target position, based on the residual rotation amount and the current speed, after the spindle axis reaches the intermediate speed; and limiting a fluctuation of a torque command of the position control, instructed to the spindle axis, to a predetermined range over a time period from a point when the spindle axis reaches the intermediate speed to a point when a predetermined elapse condition is satisfied.
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10. The method of claim 9, wherein the step of reaching the intermediate speed includes a step of successively updating a velocity command for the decelerated rotation with use of the residual rotation amount and the current speed, and making the spindle axis perform the decelerated rotation by the successively updated velocity command so that the residual rotation amount at an instant when the spindle axis reaches the intermediate speed becomes equal to a positioning rotation amount of the spindle axis required for the spindle axis to reach the target position under the position control.
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11. The method of claim 9, wherein the elapse condition comprises at least one of a condition where a predetermined time has elapsed, a condition where the current speed has decreased to a predetermined speed or below, and a condition where the residual rotation amount has decreased to a predetermined rotation amount or below.
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12. The method of claim 9, wherein the starting position corresponds to a process start position of a tapping process, and wherein the target position corresponds to a target thread depth of the tapping process.
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13. The method of claim 9, wherein the starting position corresponds to a target thread depth of a tapping process, and wherein the target position corresponds to a return completion position of the tapping process.
Specification