JP2553384B2 - Method and device for constant peripheral speed synchronous control of compound machine tool - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a constant peripheral speed synchronous control method and device in a compound machine tool. More specifically, the present invention relates to a constant peripheral speed synchronous control method and apparatus for a compound machining machine that maintains a constant turning speed at a plurality of machining positions when simultaneously performing the same machining on two or more positions.

[Prior Art] FIG. 3 shows an example of processing in which drilling and end face processing are simultaneously performed. The workpiece W is gripped and fixed to the chuck 1 fixed to the spindle. Workpiece W driven to rotate
Is processed by the cutting tool 2 from the outer circumference of the workpiece W toward the center, that is, while moving in the X-axis direction. Simultaneously with this end face machining, the drill 3 fixed to the tool post, tailstock, etc., moves in the W axis direction (axis parallel to the Z axis)
Workpiece W is fed by an axis servomotor (described later)
Is drilled. The drill 3 may be rotated by a rotary tool motor (described later) in a direction opposite to the rotation of the workpiece W instead of being fixed.

Simultaneous machining of the end surface machining with the cutting tool 2 and the hole machining with the drill 3 is a machining method which has a high machining efficiency and has been conventionally well used. The cutting tool 2 has a large diameter of the workpiece W.
The cutting speed is different when turning D ₁ and when turning small diameter D ₂ if the number of rotations of the spindle is constant. Since the cutting speeds are different, the optimum cutting speed is not always achieved in the vicinity of the small diameter D ₂ in terms of processing efficiency.

When a good finished surface of the workpiece W is required, variations in surface roughness due to changes in the cutting speed, differences in work-affected layers, and the like pose problems. Therefore, conventionally, there has been proposed and used a constant cutting speed device for increasing the rotation speed of the spindle to make the cutting speed constant in accordance with the radial position of the workpiece W on the cutting tool 2.

[Problems to be Solved by the Invention] When the above-described constant cutting speed device is applied to the above-described processing method for simultaneously performing turning at two positions, the cutting speed of the outer circumference of the drill 3 changes, and the cutting speed of the drill 3 is not necessarily changed. Not optimal cutting speed. The present invention focuses on these problems and achieves the following objects.

An object of the present invention is to provide a constant peripheral speed synchronous control method for a compound machine tool that makes a cutting speed constant at any machining position in a compound machining apparatus that simultaneously performs turning at a plurality of locations.

Another object of the present invention is to perform constant synchronous control of the peripheral speed of a compound machine tool that makes the cutting speed constant at any machining position in accordance with the rotational speed of the spindle or rotary tool in the compound machine tool that simultaneously performs turning at multiple locations. It provides a method.

[Means for Achieving the Object] The present invention employs the following means for achieving the object.

A first means is a chuck for holding a workpiece, a spindle to which the chuck is attached, a spindle servomotor for rotationally driving the spindle, a tool for turning the workpiece, a tool for simultaneously performing the tool and the workpiece. In a compound machine tool having a rotary tool for machining an object and a rotary tool servomotor for rotationally driving the rotary tool, a cutting speed between the workpiece and the tool is kept constant and at the same time the rotary tool and the workpiece are In order to make the cutting speed between the workpieces and the tool constant, the rotational speed of the spindle servomotor is controlled so that the cutting speed between the workpiece and the tool becomes constant, and the peripheral speed is kept constant. The rotational speed of the rotary tool servomotor is controlled so that the cutting speed between the workpiece and the rotary tool becomes constant, which is a constant peripheral speed synchronous control method for a compound machine tool.

A second means is a chuck for holding a workpiece, a spindle to which the chuck is attached, a spindle servomotor for rotationally driving the spindle, a tool for turning the workpiece, and a tool simultaneously with the tool. In a compound machine tool having a rotary tool for machining an object and a rotary tool servomotor for driving the rotary tool, the spindle servo for equalizing a commanded cutting speed between the tool and the workpiece. A spindle peripheral speed calculation circuit for calculating the rotation speed of the motor, and a tool peripheral speed for calculating the rotation speed of the rotary tool servomotor so as to be the same as a commanded cutting speed between the rotary tool and the workpiece. And a difference circuit for detecting the difference between the output signal of the spindle peripheral speed arithmetic circuit and the output signal of the tool peripheral speed arithmetic circuit to control the rotational speed of the rotary tool servomotor. It is a constant surface speed synchronization control system for a machining center to.

[Operation] At the same time, in a compound machine tool that processes at two or more locations, in order to make the cutting speed between the workpiece and the tool constant and at the same time make the cutting speed between the rotary tool and the workpiece constant, The rotation of the rotary tool servomotor is controlled and changed in accordance with the change in the rotation of.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a functional block diagram showing an embodiment of the present invention. The X-axis feed servomotor 8 is a drive motor for screw-feeding the cutting tool 2 in the X-axis direction. The X-axis servomotor 8 is a known DC servomotor and is an amplifier 7.
The operation is controlled by the electric power amplified by. The amplifier 7 has a D / A for converting the pulse train digital signal into an analog signal.
It is input from the converter 6.

The output shaft of the X-axis servomotor 8 is provided with a pulse generator 9 for detecting this rotation, and an analog output signal proportional to this rotation speed is fed back to the D / A converter 6 and input. Therefore, the X-axis feed servomotor 8 is rotated by the rotation speed and the rotation speed according to the command pulse train. The interpolation calculation circuit 5 that generates a pulse train to be input to the D / A converter 6 is a circuit that calculates a path given by a program from a start point to an end point and distributes the pulse.

This interpolation calculation circuit 5 is a known circuit that cooperates with an X-axis feed servomotor 8 and a Z-axis feed servomotor (not shown) to perform linear interpolation, circular arc interpolation, parabolic interpolation, and the like. The feed pulse is input from the feed pulse generation circuit 4 to the interpolation calculation circuit 5. The feed pulse is a pulse train generated by synthesizing a feed command speed commanded by a program from clock pulses. On the other hand, the spindle that drives the chuck 1 that holds the workpiece W is driven by the spindle servomotor 13.

The spindle servo motor 13 is connected to the D / A converter 1 via the amplifier 12.
It is controlled by the analog output value of 1. Spindle servo motor 1
The output shaft of 3 is provided with a pulse generator 14 and outputs an analog signal proportional to the rotation speed. This analog signal is input to the amplifier 12 and fed back.
Further, a pulse encoder 15 is connected to the output shaft of the spindle servomotor 13 to detect the rotation speed as a digital signal.

The digital output signal of the pulse encoder 15 is input to the feed pulse generation circuit 4. Feed pulse generation circuit 4
Receives this digital output signal and
Generates a feed pulse based on the rotation speed of 13 and the programmed feed command value. The input to the amplifier 12 is the D / A converter 1
Input from 1. The D / A converter 11 is the main shaft servo motor 13
Is for converting a digital signal into an analog signal so that it can be driven. The D / A converter 11 is instructed by the spindle peripheral speed calculation circuit 10 to the spindle servo motor 13 by a digital value so that the spindle speed becomes a predetermined speed.

The spindle peripheral speed arithmetic circuit 10 obtains the signal D _{1 at} the position of the bite 2 in the X-axis direction, that is, the information of the diameter from the interpolation arithmetic circuit 5,
Calculate so that the peripheral speed is constant. That is, S ₁ = 1000
Calculate × V ₁ / π × D ₁ (where V ₁ : peripheral speed m / min.,
D ₁ : workpiece diameter). The rotary tool servomotor 24 is a motor that rotationally drives the drill 3. The output of the spindle peripheral speed calculation circuit 10 is input to the difference circuit 21. The difference circuit 21 is also input from the tool peripheral speed calculation circuit 20. Tool peripheral speed calculation circuit
When the command of the cutting speed V _{2 having} a constant peripheral speed of the drill 3 and the diameter d _{2 of the} drill 3 are input, the ₂₀ calculates the rotation speed S ₂ of the drill 3 necessary for this.

That is, S ₂ = 1000 × V ₂ / π × d ₂ is calculated (where V ₂ : peripheral speed m / min., D ₂ : drill diameter). The difference circuit 21 is
The output R ₁ of the spindle peripheral speed calculation circuit 10 on the spindle side and the output S ₂ of the tool peripheral speed calculation circuit 20 on the rotary tool side are input. Difference circuit 21
Calculates the rotational speed R ₂ of the difference between the rotational speed S ₂ of the rotary tool and the command value R ₁ of the rotational speed of the spindle. The output of the difference circuit 21 is the D / A converter 2
It is converted into an analog signal by 2 and drives the rotary tool servomotor 24 through the amplifier 23. Rotary tool servo motor
The rotation speed of 24 is controlled according to the rotation speed of the spindle servomotor 13.

A pulse generator 26 is provided on the output shaft of the rotary tool servo motor 24.
It has been fed back to 23. An encoder 25 is provided on the output shaft of the rotary tool servomotor 24, and the digital output value is sent to the feed pulse generation circuit 30. A programmed feed command value of the drill 3 in the W axis direction is input to the feed pulse generation circuit 30. The feed pulse generation circuit 30 generates a feed pulse from the output value from the encoder 25 and the feed command value of the rotary tool.

This feed pulse is input to the interpolation calculation circuit 31. The interpolation calculation circuit 31 is similar to the interpolation calculation circuit 31 described above. The output of the interpolation calculation circuit 31 is output to the D / A converter 32. The D / A converter 32 converts the pulse train output from the interpolation calculation circuit 31 into an analog quantity. The D / A converter 32 rotationally drives the W-axis feed servomotor 34 via the amplifier 33. The W-axis feed servomotor 34 moves the drill 3
It is a servo motor for feeding in the axial direction (usually in the direction parallel to the Z axis). A pulse generator 35 is provided on the output shaft of the W-axis feed servomotor 34, and this value is A / D.
It is fed back to the converter 32.

Operation FIG. 2 is a flowchart showing the outline of the operation of the constant peripheral speed synchronous control device of FIG. Starts a constant peripheral speed synchronization control device (Step P _1), commanding the constant peripheral speed command to be processed at the spindle side to the circumferential speed V ₁ in byte 2 in the spindle peripheral speed computing circuit 10 (P _2). The spindle peripheral speed calculation circuit 10 is activated by this command, and the spindle peripheral speed calculation circuit 10 starts calculation in response to this constant peripheral speed command speed V _1, and a command signal of the calculated actual spindle rotation speed. Output R ₁ . The command signal R ₁ is input to the spindle servomotor 13 via the D / A converter 11 and the amplifier 12, and drives the spindle servomotor 13 to rotate and rotate the spindle.

At the same time, the speed command R ₁ of the spindle peripheral speed calculation circuit 10 is
Entered in 21. A speed command S ₂ having a constant peripheral speed on the rotating tool side is input from the tool peripheral speed calculation circuit 20 to the difference circuit 21 (P ₅ ). The difference circuit 21 takes the difference signal R ₂ between the rotation command S ₂ on the rotary tool side and the actual rotation speed command R ₁ on the spindle side (P ₆ ). This difference signal R ₂ corresponds to the actual number of rotations on the rotary tool side, and this difference signal R ₂ drives the rotary tool servomotor 24 to rotate (P ₇ ). As a result, the peripheral speed of the outer periphery of the drill 3 follows the speed change of the spindle servomotor 13 and the command speed V _{2 with a} constant peripheral speed.
Is maintained.

This constant surface speed synchronization control is continued until the programmed processing position (P _8), upon completion peripheral speed constant synchronous control device is OFF (P ₉ ~P _11). X-axis feed servo motor 8
Rotation is performed according to the pulse train of the feed pulse generation circuit 4.
That is, the bite 2 is sent in the X-axis direction at a constant pitch rate according to the rotation of the spindle servomotor 13. The drill 3 is also fed by the W-axis feed servomotor 34 in accordance with the pulse generated by the feed pulse generation circuit 30 in the W-axis direction. Therefore, both the cutting tool 2 and the drill 3 are sent with a command value of a constant pitch per one rotation. All of these feed commands are commanded by a program.

In the above-mentioned embodiment, the drill 3 is used, but the same idea can be applied to a boring tool.

[Effects of the Invention] As described in detail above, according to the present invention, it is possible to control a plurality of cutting locations at the same time by the cutting tool and the rotary tool at a constant peripheral speed, so that the machining efficiency is improved.

[Brief description of drawings]

FIG. 1 is a functional block diagram of a constant peripheral speed synchronous control device, and FIG.
FIG. 3 is an operation flow chart of the constant peripheral speed synchronous control device, and FIG. 3 is a diagram showing a processing example. 1 ... Chuck, 2 ... Bit, 3 ... Drill, 5 ...
Interpolation calculation circuit, 8 ... X-axis feed servo motor, 10 ... Spindle speed calculation circuit, 13 ... Spindle servo motor, 20 ... Tool circumference speed calculation circuit, 21 ... Difference circuit, 24 ... Rotating tool servo Motor, 30 ... Feed pulse generation circuit, 31 ... Interpolation calculation circuit, 34 ... W-axis feed servo motor

Claims (2)

(57) [Claims] 1. A chuck for holding a workpiece, a spindle to which the chuck is attached, a spindle servomotor for rotationally driving the spindle, a tool for turning the workpiece, and the workpiece and the workpiece at the same time. In a compound machine tool having a rotary tool for machining a rotary tool and a rotary tool servomotor for rotationally driving the rotary tool, a cutting speed between the workpiece and the tool is kept constant and at the same time, the rotary tool and the workpiece are In order to keep the cutting speed between the workpieces and the tool constant, the rotation speed of the spindle servomotor is controlled so that the cutting speed between the workpiece and the tool becomes constant, and the peripheral speed is made constant. A constant peripheral speed synchronous control method for a compound machine tool, wherein the rotational speed of the rotary tool servomotor is controlled so that the cutting speed between the workpiece and the rotary tool becomes constant. 2. A chuck for holding a workpiece, a spindle to which the chuck is attached, a spindle servomotor for rotationally driving the spindle, a tool for turning the workpiece, and the workpiece and the workpiece at the same time. A rotary machine for machining a rotary tool, and a rotary tool servomotor for driving the rotary tool, wherein the spindle servomotor for equalizing a commanded cutting speed between the tool and the workpiece Spindle speed calculation circuit for calculating the rotation speed of the rotary tool, and a tool peripheral speed calculation for calculating the rotation speed of the rotary tool servomotor in order to make it equal to the commanded cutting speed between the rotary tool and the workpiece. Circuit, and a difference circuit for detecting the difference between the output signal of the spindle peripheral speed calculation circuit and the output signal of the tool peripheral speed calculation circuit to control the rotational speed of the rotary tool servomotor. Constant surface speed synchronization control system for a machining center to be.